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Autor SHA1 Mensagem Data
Francois Chollet 12d068f675 Prepare PyPI release. 2016-12-19 15:34:08 -08:00
Francois Chollet 070609cbac Merge branch 'master' of https://github.com/fchollet/keras 2016-12-19 15:12:45 -08:00
Francois Chollet 6b1bf7d917 Style fixes in TF backend. 2016-12-19 15:12:33 -08:00
llcao fefb70b217 fix a bug in evaluating accuracy (#2736)
* fix accuracy computation in MNIST siamese graph example

previous code:
```
def compute_accuracy(predictions, labels):
    '''Compute classification accuracy with a fixed threshold on distances.
    '''
    return labels[predictions.ravel() < 0.5].mean()
```
is not accuracy over all the samples, but over samples with negative prediction.

* add space around  "=="

follow François's suggestion
2016-12-19 14:54:22 -08:00
Batchu Venkat Vishal 48d8853cad Allow to pass optional arguments to style transfer (#4768) 2016-12-19 14:31:07 -08:00
Francois Chollet 2a3d4722c2 Use int_shape where appropriate. 2016-12-19 14:29:22 -08:00
Francois Chollet d137d00182 Merge branch 'master' of https://github.com/fchollet/keras 2016-12-19 14:17:50 -08:00
Francois Chollet 9333179ad9 Add ability to test layers on dynamic shapes. 2016-12-19 14:12:29 -08:00
linxihui 0c842391d3 Fix issue with TF dot with dynamic shapes. 2016-12-19 14:12:04 -08:00
Gijs van Tulder 1fcb74f218 Use custom_objects to deserialize Lambda functions. (#4770) 2016-12-19 12:15:06 -08:00
Francois Chollet 1278bf9cfa Slight style fixes. 2016-12-19 12:05:28 -08:00
Francois Chollet 18e5b75f67 Generalize Dense to nD tensors. 2016-12-19 12:05:15 -08:00
Francois Chollet 766572b5b8 Add int_shape to Theano backend. 2016-12-19 12:00:24 -08:00
Keunwoo Choi 1de4d7cfba update croppings (#4765) 2016-12-19 11:15:18 -08:00
Jack Hessel 04107252f2 updated the issue template markdown with a bit more information (#4750)
* updated the issue template with a bit more information

* Update ISSUE_TEMPLATE.md

De-emphasized the google group, added StackOverflow.

* Update ISSUE_TEMPLATE.md
2016-12-17 10:45:00 -08:00
Michael Oliver 5f0e0d6c38 Fix issue #3568: allow sharing of activation function parameters along specified axes (#4141)
* allow ability to share activation parameters along specified axes

* add tests

* change to shared_axes and remove TF dummy broadcast function

* update tests to shared_axes

* Update docstrings in advanced activations
2016-12-16 17:07:10 -08:00
Julien Phalip 79406f111b Make sure that changes to the global floatx are effectively taken into account by the backend. (#4739) 2016-12-16 16:59:01 -08:00
Francois Chollet 30fa61d457 Use tf.select instead of tf.where (compat TF 0.11) 2016-12-16 16:37:55 -08:00
Francois Chollet 914d976801 Fix compatibility with TF 0.11. 2016-12-16 16:15:02 -08:00
Francois Chollet 839d4f108e Merge branch 'master' of https://github.com/fchollet/keras 2016-12-16 15:44:10 -08:00
Francois Chollet 5e73db6c00 Handle recent TF API changes. 2016-12-16 15:43:58 -08:00
Charles-Emmanuel e9b8424839 Theano backend consistancy (#4748)
* Theano backend consistancy

ones_like and zeros_like don't have the name parameter in their signature for theano backend so it can trigger an error if it is used.

* pep8

pep8
2016-12-16 13:52:31 -08:00
Francois Chollet e3dd5d7ca5 Tmp bugfix 2016-12-16 12:53:16 -08:00
Francois Chollet 2752a58730 Tmp bug fix 2016-12-16 12:43:11 -08:00
Francois Chollet 69eb5752ce Update README. 2016-12-16 12:40:55 -08:00
Francois Chollet 9090704f1d Update the TF backend documentation. 2016-12-16 12:38:11 -08:00
Keunwoo Choi fa9f863dbf Documentation - tensorflow_backend (#4677)
* documentation - tensorflow_backend.py - first 1/3

* pep8, add periods.

* documentation - tensorflow_backend.py

* pep8

* * fix the confusion of variable/tensor.
* remove `var` as a variable name. `kvar` is used instead.
* new lines between multiple items under # Arguments
2016-12-16 11:42:39 -08:00
Bohumír Zámečník 4b1b706aa4 Fix a typo in Cropping3D docs. (#4742)
saptio -> spatio
2016-12-16 10:26:24 -08:00
Francois Chollet 5e75b8506c Uniquify updates in Theano backend functions. 2016-12-15 17:02:35 -08:00
Francois Chollet bc9f341165 Update docs wrt custom layer writing. 2016-12-15 14:05:09 -08:00
PPACI b40b8a00e4 Now properly set self.y to None in NumpyArrayIterator (#4732) 2016-12-15 10:05:50 -08:00
Su Tang d811048887 Add python3 support for some examples (#4715) 2016-12-14 23:07:21 -08:00
fchollet 0ba2626bd2 Further style fixes 2016-12-14 22:39:18 -08:00
fchollet c6eea03c8d Style fixes in engine. 2016-12-14 22:09:05 -08:00
Francois Chollet 0fd0218ef0 Various style fixes. 2016-12-14 15:22:49 -08:00
Francois Chollet 5e1a5d07c4 Style fixes in layers/pooling.py. 2016-12-14 15:08:13 -08:00
Francois Chollet 518fa3aa44 Style fixes in layers/local.py. 2016-12-14 15:04:34 -08:00
Francois Chollet ef1da479ec Display count of trainable params in summary. 2016-12-14 14:25:06 -08:00
Alejandro Dubrovsky 3f12d7ae44 Add a 'period' variable to ModelCheckpoint to save every period epochs (#4687)
* Add a 'period' variable to ModelCheckpoint to save every period epochs

* Update callbacks.py
2016-12-14 14:02:23 -08:00
Gijs van Tulder c4579a9c43 Fix dimshuffle problem in old Theano batch_normalization. (Fixes #4697.) (#4713) 2016-12-14 13:55:34 -08:00
François Chollet ff62eb251b Refactor regularizers and add add_weight method. (#4703)
* Refactor regularizers, introduce layer.add_weight

* Fix BN add_update syntax

* Fix eigenvalue regularizer

* Style fixes.
2016-12-14 13:41:24 -08:00
Francois Chollet 2b336756b6 Set default backend to TF on windows. 2016-12-13 19:49:49 -08:00
Francois Chollet 0f0d8be884 Further style fixes. 2016-12-13 19:49:36 -08:00
Francois Chollet 3f3e0aa90e Style fixes in models.py. 2016-12-13 19:23:16 -08:00
Francois Chollet c0ee5b859c Further style fixes in TF backend. 2016-12-13 19:14:44 -08:00
Francois Chollet edae178532 Style fixes in utils. 2016-12-13 19:13:04 -08:00
Francois Chollet a0a0308061 Style fixes in sklearn wrapper 2016-12-13 18:58:45 -08:00
Francois Chollet 74329d0c1d Style fixes in backend/tensorflow_backend.py. 2016-12-13 18:55:55 -08:00
Francois Chollet 5777355972 Fix style issues in backend/theano_backend.py. 2016-12-13 18:37:23 -08:00
Francois Chollet 0272587c29 Fix style issues in core.py. 2016-12-13 18:36:25 -08:00
Francois Chollet 22d3c8810c Style fixes in engine/topology.py. 2016-12-13 17:44:07 -08:00
Francois Chollet 4aa8aa100b Style fixes in training.py. 2016-12-13 15:47:12 -08:00
Francois Chollet bd404b1c88 Add TF exception to SWWAE example 2016-12-13 13:01:58 -08:00
Francois Chollet bed17efae8 Merge branch 'master' of https://github.com/fchollet/keras 2016-12-13 12:53:41 -08:00
Jan Zikes 8d0199ed42 Replaced old tensorboard calls by calls compatible with tensorflow 0.12 (#4700)
* Added update towards tensorflow 0.12 (replaced deprecated calls by new ones)

* added backwards compatibility with tensorflow<=0.11.0
2016-12-13 11:17:44 -08:00
fchollet 9f33f8af5f Add names to Keras application models 2016-12-12 19:17:41 -08:00
Francois Chollet 7c4f033c6a Change optimizer in CIFAR10 example. 2016-12-12 16:02:43 -08:00
Francois Chollet 7e2e7a5e5a TB callback: close writer on train end. 2016-12-12 16:01:03 -08:00
Francois Chollet 909fbd19ea Update answer to validation split Q in FAQ 2016-12-12 15:56:56 -08:00
Francois Chollet 2b27ab1c9e Merge branch 'master' of https://github.com/fchollet/keras 2016-12-12 15:05:47 -08:00
Francois Chollet d244d38047 Backwards compatibility fix 2016-12-12 15:05:35 -08:00
Gijs van Tulder 2a0b112d08 Use Theano's abstract interface for batch normalization (#4595)
* Simplify BatchNormalization code.

* Make Theano's K.batch_normalization similar to TensorFlow.

* Change default batch normalization epsilon to 1e-3.

* Use Theano's new batch normalization interface.
2016-12-12 14:17:59 -08:00
Francois Chollet d9657b70c0 Merge branch 'master' of https://github.com/fchollet/keras 2016-12-12 23:09:19 +01:00
Francois Chollet e8939f43a6 Fix BN reuse issue in TF backend 2016-12-12 23:09:04 +01:00
sunil-at-gh 8e587fb17a Fix for issue #4640: MaxPooling1D with border_mode='same' caused h_pad to take illegal value -1 in theano_backend:pool2d. (#4683)
Added test case.
2016-12-12 14:08:04 -08:00
dathinab 757ae95cca Fixes #4690, check for bool dtype in K.mean (th0.9) (#4691)
(It also adds a docstring, like in the tf backend)
2016-12-12 13:56:05 -08:00
Leszek cc6e65d145 recurse directories in DicrectoryIterator (#4657)
* recurse directories in DicrectoryIterator

rebased and squashed, again

* added prose about new behaviour of flow_from_directory

also, about BMP files.
2016-12-11 09:57:28 +01:00
Francois Chollet df464c103e Remove pypi version badge 2016-12-11 09:22:22 +01:00
Keunwoo Choi d517b55576 Documentation - Add # Argument # Return # Example in backend/common.py (#4668)
* Add # Argument # Return # Example in backend/common.py

* * pep8
* debug (a mistake by me)

* * Remove useless docstrings, remove `None` returns
* Add bullet points

* argument→arguments, return→returns, example→examples

* Update common.py

* Update common.py
2016-12-11 03:38:20 +01:00
Daniel Angelov 4c1353c188 Added Convolution3D as a layer supporting the regularizers and constraints API. (#4673) 2016-12-10 19:15:38 +01:00
Francois Chollet 4871208f02 String cleanup 2016-12-10 11:33:09 +01:00
Francois Chollet 08566f22c7 Allow 4-channel images in preprocessing/image.py 2016-12-10 11:21:53 +01:00
Francois Chollet ea7b37a42a Merge branch 'master' of https://github.com/fchollet/keras 2016-12-10 11:18:35 +01:00
Adam Wentz 302eef7bad Add arange to both backends (#4350) 2016-12-10 11:15:00 +01:00
Gijs van Tulder 825adad18d Theano: deconv2d should also shuffle filter_shape. (#4631) 2016-12-10 09:58:32 +01:00
Francois Chollet 4491212da4 Remove unnecessary import 2016-12-09 12:16:51 +01:00
Francois Chollet 52e2f3ed64 Slight style fixes in example 2016-12-09 11:59:35 +01:00
Leszek 1de4fe0ba8 changed order of tests for theano (#4643)
shortest first. if they fail, stop testing.
2016-12-08 13:09:43 +01:00
Guy Hadash e1208f5b9f Adding preprocess function to ImageDataGenerator (#4620)
* addition option for preprocess function in ImageDataGenerator

* fixes according to comment
2016-12-08 10:34:22 +01:00
Yongsheng Xu 0a8ac44617 change dockerfile to fit the latest version of tensorflow and cuda (#4642) 2016-12-08 10:26:19 +01:00
Shaofan Lai 1fd2108bcf fix load_model so that it can load customized optimizer (#4625) 2016-12-07 11:13:36 +01:00
Pat York ad5e29a2b7 Added JSON content headers (#4603) 2016-12-05 09:18:01 +01:00
Francois Chollet 93b7dd9915 Close file after writing in TB callback. 2016-12-04 23:25:30 +01:00
Francois Chollet 9256b76226 Merge branch 'master' of https://github.com/fchollet/keras 2016-12-04 22:54:00 +01:00
Francois Chollet fbd12f7d44 Fix issue with LSTM dynamic masking. 2016-12-04 22:53:45 +01:00
Shijie Wu 90c4895a7a Fix document in convolutional_recurrent.py (#4586)
* Fix mismatch of interface and document in convolutional_recurrent.py

* Update document of convolutional_recurrent.py to match the interface
2016-12-04 22:34:05 +01:00
Francois Chollet 6dfa8b1d60 Update FAQ entry about intermediate output display 2016-12-04 19:11:17 +01:00
Francois Chollet 5430844453 Fixes to image preprocessing utils 2016-12-04 18:57:15 +01:00
Francois Chollet 9dd06082e7 Merge branch 'master' of https://github.com/fchollet/keras 2016-12-04 17:15:10 +01:00
Francois Chollet cb4f93913e Fix shape validation issue with imagenet_utils 2016-12-04 17:14:57 +01:00
ηzw 149946c706 Fix typos (#4591) 2016-12-04 04:05:34 -08:00
Francois Chollet 78988b5cd6 Fix serialized Merge output shape loading 2016-12-04 13:02:36 +01:00
Gijs van Tulder a081e049db Use Theano's IfElse instead of Switch for in_train_phase. (#4579)
This should allow Theano to perform lazy evaluation.
2016-12-02 16:25:11 -08:00
Francois Chollet 68af216772 Fix issue with custom Application input_tensor 2016-12-02 14:35:50 -08:00
Keunwoo Choi b4a532e970 adds keras.json details in backend document (#4560) 2016-11-30 23:18:48 -08:00
Francois Chollet 3bf913dc35 Unflake optimizer test 2016-11-30 21:11:53 -08:00
Taras Boiko 55163b5999 Warn when output shape not specified for Lambda on Theano (#4543) 2016-11-30 20:47:44 -08:00
Brett Naul 9bfbe6ae3e Fix deprecation warning in to_categorical (#4547) 2016-11-30 20:46:15 -08:00
Amane Suzuki b23e873e0f Fix small typo (#4559)
* Fix small typo

* Fix small typo
2016-11-30 20:44:54 -08:00
Fariz Rahman 79ec9b8079 ACGAN : Remove lines with no effect (#4503)
* Remove lines with no effect

* pep8

* Update mnist_acgan.py
2016-11-29 13:22:34 -08:00
Javier Dehesa 24d6cca275 Enforce shape invariance for states in RNN loop (#4536)
Fixes some shape invariance errors arising sometimes when building RNNs.
2016-11-29 11:31:14 -08:00
lebavarois 83b90c172c change to new tables api (#4526) 2016-11-28 13:35:05 -08:00
fchollet 57f2f11005 count_params should report count for all weights. 2016-11-26 21:08:21 -08:00
fchollet bf502be578 Merge branch 'master' of ssh://github.com/fchollet/keras 2016-11-26 20:08:46 -08:00
fchollet dfeca151a2 Allow to set input shape in CV models. 2016-11-26 20:08:41 -08:00
Francois Chollet 2ddd2bd557 Prepare new PyPI release 2016-11-25 20:52:27 -08:00
Ken Chatfield b2aebb30bf Don't add another header line to CSV logger when appending to an existing file (#4426) 2016-11-25 14:49:50 -08:00
Fariz Rahman 0a9c0ca461 Sequential : Fix trainable arg (#4509) 2016-11-25 11:59:05 -08:00
fchollet c0b32a9a04 Remove reference to legacy Graph model in tests. 2016-11-25 01:20:10 -08:00
fchollet 703d5a1298 Add dynamic trainability lightweight test 2016-11-24 23:59:51 -08:00
fchollet c5cc96a4f4 Saner way to collect trainable weights 2016-11-24 23:59:33 -08:00
fchollet de256cb5d5 Make sure ImageNet predictions are sorted 2016-11-24 23:30:00 -08:00
fchollet ce814302ac Remove support for legacy Graph model 2016-11-24 23:29:45 -08:00
Fariz Rahman 628bc6e03e ACGAN: Remove unnecessary dimension in label input (#4501) 2016-11-24 20:21:56 -08:00
Thomas Pinetz dfb606bb19 Fix border_mode = same for pooling layers documentation. (#4341) 2016-11-24 12:42:59 -08:00
Dontloo 88f3b3f75e fixed variational autoencoder visualization for Gaussian latent space (#4423) 2016-11-23 14:08:19 -08:00
Marzuk Kamal 773d4ce8cb def fbeta_score(y_true, y_pred, beta=1) (#4492)
set the default value of beta=1
2016-11-23 13:25:29 -08:00
Fariz Rahman 509d6d8235 Merge : Serialize output mask; Enable user arguments for callable mode (#4445)
* Update topology.py

* Update topology.py

* Update topology.py

* white space fix

* indentation fix

* add tests

* fix all tests

* add arguments arg to merge

* space after period

* add test with arguments

* add test with arguments for lambda layer too

* pep8 fixes

* fix tf test

* try fixing tf test; again

* bug fix

* finally
2016-11-23 13:24:54 -08:00
Taras Boiko 7bd5c862a2 Correctly check the output dimension for None instead of target (#4458) 2016-11-23 13:21:48 -08:00
Angelos Katharopoulos 2878f60634 Add map, foldl, foldr to the backend (#4461) 2016-11-23 13:21:13 -08:00
Luke de Oliveira 50fdb87888 adding mnist acgan example (#4475) 2016-11-23 13:19:29 -08:00
Gijs van Tulder dad7790ec3 Model summary: separate columns with a space. (#4469) 2016-11-23 11:06:30 -08:00
Marzuk Kamal 709bc5e15a tf.global_variables and tf.variables_initializer (#4490)
tf.all_variables and tf.initialize_variables are replaced by tf.global_variables and tf.variables_initializer for the future version of tensorflow
2016-11-23 11:06:10 -08:00
Ken Chatfield 06cc6d7fea Add initial epoch argument to fit functions (#4429)
* Added initial_epoch argument to fit functions in trainer

* Added unit test

* PEP8 fixes
2016-11-19 21:51:57 -08:00
EdwardRaff 97484ec9c1 Finishing Colincsl's SpatialDropout1D (#4416)
* Added SpatialDropout1D

This is a straightforward modification of SpatialDropout2D but for 1D data.

* Added SpatialDropout1D to docs

* SpatialDropout1D test

* Fixed indent issue

* Combined TF and TH dimension conditions

Use the same 1D dimensions for TensorFlow and Theano in SpatialDropout1D.

* trailing whitespace

* Removed dim_ordering variable

* Removing dim_ordering values

removing dim_ordering values as requested
2016-11-19 12:30:05 -08:00
Taras Boiko 6b04add932 Check all output dimensions for compatibility (#4420) 2016-11-19 10:10:08 -08:00
Yu Kobayashi 04ea01f385 Bug fix of Bidirectional(LSTM(..., stateful=True)) (#4424)
* Bug fix of Bidirectional(LSTM(..., stateful=True)) https://github.com/fchollet/keras/issues/4421

* Add Recurrent.from_config() test
2016-11-18 12:19:42 -08:00
Yu Kobayashi 8653060ae6 Update Travis TensorFlow to 0.11.0 (#4367) 2016-11-17 09:55:39 -08:00
Francois Chollet 8df3effa5f Merge branch 'shareable_bn' 2016-11-16 19:07:06 -08:00
Francois Chollet 771010f43b Add shareable BN (per-datastream updates). 2016-11-16 19:06:46 -08:00
Carl Thomé 8d20bac7fa Remove extraneous batch_input_shape (#4393) 2016-11-16 18:59:03 -08:00
Francois Chollet c4c4fac1ae Make BN shareable (not yet working) 2016-11-15 05:16:40 -08:00
Francois Chollet 016d85c9e6 Minor style fixes 2016-11-14 15:09:58 -08:00
Francois Chollet 3ab29205fc Merge branch 'master' of https://github.com/fchollet/keras 2016-11-14 15:08:04 -08:00
Francois Chollet fdd150eb4d Minor style fixes 2016-11-14 15:07:51 -08:00
Anton Chernyavski 789a2be8d9 Fix get_layer() by index (#4376) 2016-11-14 09:47:27 -08:00
Francois Chollet ae7ef37c1b Merge branch 'master' of https://github.com/fchollet/keras 2016-11-09 20:57:43 -08:00
Francois Chollet 94fba3d8f0 Fix Theano tests 2016-11-09 20:57:30 -08:00
Yu Kobayashi 6ac9af0a5a Fix the load_model() bug by sorting weights by names (#4338) 2016-11-09 20:36:45 -08:00
Francois Chollet e916f748db Fix Theano tests 2016-11-09 20:33:42 -08:00
Francois Chollet 92e8a20761 Remove unused set_input method 2016-11-09 18:34:09 -08:00
Francois Chollet cb3de665d1 Simplify tests 2016-11-09 18:01:19 -08:00
Francois Chollet 49a5cdf76d Improve error message 2016-11-09 18:01:06 -08:00
Francois Chollet 08a090de43 Merge branch 'master' of https://github.com/fchollet/keras 2016-11-09 17:33:49 -08:00
Francois Chollet fa3b17cd96 Minor code cleanup 2016-11-09 17:33:31 -08:00
Ken Chatfield 5266fdacf1 Bugfix to CIFAR pickle reading code in Python 3 (#4319) 2016-11-09 17:14:36 -08:00
nagachika b74c5953f0 Print EarlyStopping verbose message on_train_end. (#4332)
The message print on_epoch_end would be overwritten by ProgbarLogger.
2016-11-09 16:35:22 -08:00
Yu Kobayashi 00e8d20eae Theano tile() expects Python int, so casting from numpy.int32 to Python int. (#4330) 2016-11-09 16:23:22 -08:00
Gijs van Tulder e8e63e307e Theano: try not to use the old pool_* interface. (#4321) 2016-11-09 16:22:37 -08:00
Uwe Schmidt 7db6de848a Fix for issue #3965 (#4333)
* Fixes issue with resize_images and partially-definded tensors

Disclaimer: I haven't tested this with `dim_ordering == 'th'`

* PEP8 syntax
2016-11-09 16:21:37 -08:00
Matt Gardner 8360ef3a5a Add documentation to set self.built = True in MyLayer.build() (#4315)
* Added documentation to set self.built = True in MyLayer.build()

* Update writing-your-own-keras-layers.md
2016-11-07 18:19:27 -08:00
Francois Chollet d32b8fa4bd Further code cleanup 2016-11-07 17:27:41 -08:00
Francois Chollet c95c32e473 Improve docstrings 2016-11-07 15:36:57 -08:00
Francois Chollet 02fe371839 Merge branch 'master' of https://github.com/fchollet/keras 2016-11-07 12:46:54 -08:00
Francois Chollet b7b7c2ea94 Normalize default argument values 2016-11-07 12:46:41 -08:00
Francois Chollet 105dd031dd Documentation improvements 2016-11-07 12:46:18 -08:00
Joshua Loyal 4fa289166a allow for learning rate dtypes returned by numpy (#4304) 2016-11-07 10:33:11 -08:00
Carl Thomé a8bbcf611f ConvLSTM2D docstring spelling (#4306)
* Spelling

* "convolutionnal" spelling
2016-11-06 12:05:20 -08:00
Francois Chollet d5030b1f8c Add conv_lstm to examples/README 2016-11-05 15:30:33 -07:00
Francois Chollet f127b2f81d Merge branch 'imodpasteur-rebasedconvV1' 2016-11-05 13:46:02 -07:00
Francois Chollet 9d4087a1e9 Style fixes 2016-11-05 13:45:50 -07:00
Francois Chollet fd326ddf1b Merge branch 'rebasedconvV1' of https://github.com/imodpasteur/keras into imodpasteur-rebasedconvV1 2016-11-05 13:32:03 -07:00
Francois Chollet 7f42253f46 Add basic support for TF optimizers, part deux 2016-11-05 13:26:03 -07:00
Francois Chollet 18d7e5e6e4 Style fixes 2016-11-05 13:22:18 -07:00
Francois Chollet 6610880fd4 Merge branch 'master' of https://github.com/fchollet/keras 2016-11-05 13:21:38 -07:00
Arbona 11b73ae6b4 Tf dynamic 2016-11-04 21:20:30 +01:00
Carl Thomé 2b51317be8 Refactor F-score into precision and recall metrics (#4276)
* Refactor f-score into precision and recall metrics

* Docstring consistency

* Add docstring for fmeasure

* Added precision, recall, f-measure tests
2016-11-03 20:28:04 -07:00
Francois Chollet 650c2c8cf9 Add basic support for TF optimizers 2016-11-03 11:38:00 -07:00
Igor Macedo Quintanilha 49386e8da4 Bug fix when target is a SparseTensor. (#4200)
* Bug fix when target is a SparseTensor.
Check for sparsity when creating target placeholder.
Remove shape argument when creating sparse placeholder.

* Fixed ndim behavior for sparse tensor

* Fix sparse variable instantiation.

* Bug fix
2016-11-03 10:04:40 -07:00
Thang Bui 71494ffdbc changed VAE sampling variance to 1 (#4211)
* Update variational_autoencoder.py

fixed sampling bug

* Update variational_autoencoder_deconv.py

fixed variance bug
2016-11-02 15:58:32 -07:00
Francois Chollet a9b6bef062 Improve dynamic TF RNN implementation. 2016-11-02 11:51:29 -07:00
Francois Chollet 4840e435f7 Improve RNN error messages 2016-11-02 10:47:46 -07:00
Arbona 531147c877 Fix review 2016-11-02 12:08:31 +01:00
Francois Chollet 61c21ef9ee Imagenet predictions sorting fix 2016-11-01 17:39:39 -07:00
Francois Chollet 058e54061b Style fixes 2016-11-01 17:39:23 -07:00
Francois Chollet 32be731194 Some backend refactoring 2016-11-01 16:52:25 -07:00
Francois Chollet 9bf55395f1 Simplify 1D pooling implementation 2016-11-01 16:51:54 -07:00
Francois Chollet 114b82a212 Minor TF backend improvements 2016-11-01 15:26:01 -07:00
manelbaradad 7d143370d8 BUG: Deconvolution2D output shape not correctly referenced (#4251) 2016-11-01 11:24:54 -07:00
Gijs van Tulder bc6880fa34 Enable full convolution with the Theano backend. (#4250) 2016-11-01 11:03:50 -07:00
Francois Chollet c6d2ccd453 Prepare 1.1.1 release. 2016-10-31 13:12:59 -07:00
Francois Chollet cdab739471 Merge branch 'master' of https://github.com/fchollet/keras 2016-10-31 13:11:49 -07:00
Taras Boiko fee03bd5a6 Use six for wrapping in keras_test (#4235)
This will allow parameterized tests to work correctly in both 2.7 and
3.4
2016-10-31 10:51:32 -07:00
Aloïs Gruson 6fd2d43bfe Fix Theano Cudnn BatchNorm when axis!=1 (#3968)
* fix batch_norm when axis!=1

* fix dimshuffle for all backends

* moving cudnn bn fix to theano backend

* fix pep8

* dont use cudnn when bn axis is non broadcastable, ie dim=1
2016-10-28 10:51:32 -07:00
Arbona 40fd415409 Changed name example 2016-10-27 10:46:54 +02:00
Laurent Gautier 9c7020f7e7 Only allow the addition to Sequential objects of layers that are instances of Layer (#4184)
* Check that the added object is an instance of class Layer

* Update models.py

* Fix ValueError error message
2016-10-26 11:02:10 -07:00
Sean 556399cc48 Add more util docs (#4154)
* Add more util docs

* Leave out single use utils
2016-10-26 10:40:33 -07:00
Ramanan Balakrishnan bef888c2d8 add new min_delta parameter in EarlyStopping to stop in cases of minimal improvements (#4202) 2016-10-26 10:39:52 -07:00
Stefan Wunsch a89dabe0cd Enhance doc about usage of sample weights in validation data tuple (#4199) 2016-10-26 10:18:59 -07:00
Alexander Rakhlin 80fbbc3a6a Bug fix in zca_whitening (#4181)
When calculating 'sigma' denominator is # of instances (axis=0), not dimensionality (axis=1)

Proof:
http://ufldl.stanford.edu/wiki/index.php/Implementing_PCA/Whitening
http://ufldl.stanford.edu/wiki/index.php/Exercise:PCA_and_Whitening
Ng uses 2nd dim in denominator because his matrix is features x instances
2016-10-25 10:40:03 -07:00
Carl Thomé 7a6ee934e1 Display wrapped layers in graph visualization (#4169)
* Display wrapped layers in graph visualization

* Check parent class instead of class's module

* Check instance instead for brevity

* More consistent naming
2016-10-25 09:40:14 -07:00
Arbona 8b11f13507 Changed name 2016-10-25 17:45:28 +02:00
Francois Chollet 4401120ca6 Style fixes 2016-10-24 15:49:38 -07:00
Michael Dietz 8dd61c1dc4 Fixed https://github.com/fchollet/keras/issues/4048 : in TensorBoard callback which fails when it is not the only callback (specifically when another cbk is ReduceLROnPlateau). (#4159) 2016-10-24 15:13:39 -07:00
Roberto de Moura Estevão Filho 6849589430 Fix LiL sparse matrix on Tensorflow (#4173)
LiL sparse matrices would not work correctly due to dtype being
different. Using the sparse_coo data fixes it.
2016-10-24 13:33:45 -07:00
Jaye 4cd83631ee Update imdb_cnn.py to use GlobalMaxPooling1D (#4164) 2016-10-24 09:25:08 -07:00
Felix Sonntag 028aae19bf Fixes for Python 3 (#4121)
* Fixed weights.sort for Python 3

In Python 3 weights.sort could throw a TypeError exception, if the
names are all None

* Fixed _flattened_layers under Python 3

If self.layers is empty, an IndexError appears when accessing it. So
it’s necessary to check if it’s non-empty first

* Fixed weight sorting for Theano backend

* Added missing import statement

* Improved backend handling for weight calculation

* Simplified weight sorting and backend check

* Changed behavior of weights sorting

* Removed unnecessary import
2016-10-23 09:01:16 -07:00
jarfo 41741c38e5 Keep shape of the initial (dummy) state (#4146)
tensorflow breaks if the shape of the state changes
https://github.com/fchollet/keras/issues/4008
2016-10-22 20:23:02 -07:00
Thomas Boquet 3feca20c59 + multiprocessing in legacy - unused imports (#4139) 2016-10-21 14:58:28 -07:00
Johan Pauwels f1bc3c03ed Make build_fn argument of sckit-learn wrappers accept class methods (#4107) 2016-10-20 15:33:56 -07:00
Fariz Rahman 66e5944799 Fix Merge layer docstring (#4132) 2016-10-20 15:23:10 -07:00
Francois Chollet 6ffa6f39e6 Fix typo in Merge layer docstring. 2016-10-19 14:10:17 -07:00
Francois Chollet 94ee8e1570 Add Xception model to keras.applications. 2016-10-19 14:06:07 -07:00
happygds 3e95633b1f manually terminate threads process returned by generator_queue() (#4101)
* manually terminate threads process returned by `generator_queue()`

Recently I custum a video sequence DataGenerator (based on ImageDataGenerator) for experiment. When I use model.fit_generator as following:
>history = model.fit_generator(train_data_generator, samples_per_epoch=train_data_generator.nb_sample,
                              nb_epoch=nb_epoch, verbose=1, callbacks=[early_stopping, model_checkpoint],
                              validation_data=test_data_generator, nb_val_samples=test_data_generator.nb_sample,
                              max_q_size=10, nb_worker=8, pickle_safe=True)
I found that the validation process consumes much longer time than training despite it contains less data.
I read the code and changed the `self.evaluate_generator()` (line 1482) in `fit_generator' to use a multiprocessing approach as training process did. However, the memory usage quikly increases and it only last for a few epoches. 
Through analysis, I think it is caused by the processes weren't freed after the `evaluate_generator` accomplished. Thus I suggest returning `generator_threads` from function `generator_queue()` and manually terminate these threads in `fit_generator`, `evaluate_generator`, `predict_generator`.

* stastify the PEP style

* correct the PEP8's E128 error
2016-10-18 20:34:50 -07:00
Ramanan Balakrishnan 70ebb15a33 Add documentation about metrics functions (#4024)
* Add documentation about metrics functions

* Add docstrings to metrics.py and auto-generate the docs from these strings
2016-10-18 19:57:42 -07:00
Gijs van Tulder d745d9ee96 Use Theano's pool_3d function. (#4065) 2016-10-16 22:27:15 -07:00
Abishek Bhat b89a93faae Remove unused imports. (#4083) 2016-10-16 21:58:35 -07:00
Vijay Vasudevan 044071f0d5 Switch use of TF cond function to use public function. (#4064)
* Switch use of TF cond function to use public function.

Prior to newer TFs, cond was unavailable and thus was being
imported via private module namespaces.

Newer TFs expose tf.cond as the public interface.  There
are plans to remove private module namespace access so
this fixes keras to first try accessing through the public
namespace, and then going through the private one for older
versions of TF.

* PEP8 fix
2016-10-14 14:27:15 -07:00
ηzw 79c1331432 Remove unused import statement (#4053) 2016-10-14 09:16:56 -07:00
Jayanth Koushik 86f28494a5 Return decay from get_config of all optimizers (#4052) 2016-10-13 15:25:50 -07:00
Yu Kobayashi d53a1cd0c0 Python 3 support of image_ocr.py (#4049)
I fixed to support Python 3.
2016-10-13 13:53:35 -07:00
Arbona 2c96373a41 remove another useless check 2016-10-13 21:30:01 +02:00
Arbona 731e1bb206 remove a useless check 2016-10-13 21:28:51 +02:00
Arbona c1a72b3644 More test and fixed dropout 2016-10-13 20:58:01 +02:00
fchollet e52740f09a Add Gitter link to README 2016-10-12 20:11:43 -07:00
fchollet 5dd8c5c10c Padding style fixes. 2016-10-12 18:02:39 -07:00
Dmitry Lukovkin 169c0896d6 Make ZeroPadding2D optionally asymmetric (#3595)
* Make ZeroPadding2D and ZeroPadding1D optionally asymmetric

* Make padding argument polymorphic.
Add test case for asymmetric padding.
Remove excessive imports.

* Fix layer config saving.

* Duck typing (as soon as test passes tuple as a list)

* Doc update

* Set padding value for the missing keys to 0.
Raise exception if unexpected keys are found in the padding dict.

* Add test for ZeroPadding1D
2016-10-12 17:48:57 -07:00
ftence 1bc0468ada Applied imagenet mean pixel on BGR instead of RGB. (#4027) 2016-10-12 16:59:56 -07:00
Gijs van Tulder 9a411f367d Use Theano's new theano.nnet.conv3d interface. (#4039) 2016-10-12 16:57:50 -07:00
Jayanth Koushik 6074a18ec4 Fixed typo in Adamax (#4043)
Fixed a typo in Adamax which prevented it from using explicit decay.
2016-10-12 16:57:22 -07:00
Arbona 0e7f3e04b0 pep fixed 2016-10-12 22:11:22 +02:00
Arbona 53552b1d6e Various fix 2016-10-12 22:00:55 +02:00
Taras Boiko d7d1db5d79 Test AveragePooling2D in test_average_pooling2d (#4034) 2016-10-12 08:21:21 -07:00
Fariz Rahman 9d7a2338b4 imdb fasttext speedup (#4026)
* imdb fasttext speedup

* Lambda -> GlobalAveragePooling1D
2016-10-11 11:01:11 -07:00
Taras Boiko 6e42b0e4a7 Added ability to return more than one metric from a function (#3907) 2016-10-11 10:54:02 -07:00
Gijs van Tulder ef7911310d Use Theano's cuDNN batch normalization for training. (#4023) 2016-10-11 10:52:07 -07:00
Ramanan Balakrishnan 999f402829 add KL divergence to metrics (#4025) 2016-10-11 10:50:44 -07:00
Bas Veeling 85c2d28e99 ReduceLROnPlateau fix for cooldown=0 (Fixes #3991) (#4011) 2016-10-10 13:18:58 -07:00
Arbona 6b7421c448 Various fix 2016-10-09 10:46:04 +02:00
fchollet 7df184d3aa Style touch-ups 2016-10-08 15:53:24 -07:00
Abishek Bhat 197005a791 Correct metrics usage in getting started guide. (#3993)
As the code
[here](https://github.com/fchollet/keras/blob/master/keras/engine/training.py#L662) suggests whenever a model is compiled with `metrics = [name_of_the_metric_function]` works, however, the documenation suggests that `accuracy` is the only supported string representation.
2016-10-07 23:34:21 -07:00
Ramanan Balakrishnan 52ee2380e4 Add top-k classification accuracy metrics (#3987)
* add categorical accuracy metric which tracks over top-k predictions

* remove top_k_categorical_accuracy from being tested together with other all_metrics

* fix in_top_k to work with batches. correct metrics.py and test_metrics.py appropriately

* style fixes for documentation on in_top_k function

* default to k=5 for top_k_categorical_accuracy metric
2016-10-07 23:32:19 -07:00
Anish Shah 530eff62e5 [issue #3942] Add GlobalMaxPooling3D and GlobalAveragePooling3D (#3983) 2016-10-07 15:06:19 -07:00
Francois Chollet 4de7eaa6a8 Update docs 2016-10-06 15:38:01 -07:00
Francois Chollet 8281988842 Style fixes 2016-10-06 15:01:17 -07:00
Francois Chollet 4ed7138685 Style fixes 2016-10-06 14:55:22 -07:00
Carl Thomé 6689189819 Add F-score metric to metrics.py (#3895)
* Added optional path argument

* Added optional field name argument

* Added LambdaCallback callback

* Fixed on_epoch_begin assignment

* Match default signatures

* Whitespace

* Test LambdaCallback examples

* Only test process termination

* Imports

* Fixed test

* Wait on process to terminate

* Add zero threshold and set F measure to zero if no true samples exist

* Reduce zero threshold

* Flip thresholded non-zero count

* Add F measure test

* Updated test

* Remove lambda, simplify

* Whitespace

* Update docstring

* Update test

* Whitespace
2016-10-06 14:53:53 -07:00
Emad El-Haraty 0ce7e4976a Descriptions of examples as a README.md file, allowing for easier browsing in github (#3982) 2016-10-06 11:17:22 -07:00
Hengkai Guo 6b18a908b8 Fix shape inference error for newly version Tensorflow in ctc_label_dense_to_sparse (#3955) 2016-10-04 11:21:31 -07:00
Gunnar Läthén 570fdf31c5 Python3 fix for deserialization of closures (#3961) 2016-10-04 11:16:44 -07:00
Seonghyeon Nam 929669bd1b Remove a print message when using global pooling (#3963) 2016-10-04 11:15:16 -07:00
Roberto de Moura Estevão Filho 240fd5b68e Fix control_flow_ops import (#3948)
* Fix control_flow_ops import

Old access was not working on new version of tensorflow. This should
work for all versions.

* Fix identation
2016-10-03 09:42:16 -07:00
Arbona 1d0d79f61a Various fix 2016-10-03 11:43:24 +02:00
Arbona b5dddeb419 Removed notebook and added example in python 2016-10-03 10:45:53 +02:00
Andre Simpelo 9194052a94 Fixed dead link in batch norm documentation (#3937)
Fixed dead link for the references in the Batch Normalization documentation
2016-10-01 20:37:42 -07:00
fchollet e0d871b7dc Restructure docs for Applications module 2016-10-01 15:19:12 -07:00
Sean c455a19f8e Change HDF5Matrix so start and end are optional (#3933) 2016-10-01 12:55:31 -07:00
Francois Chollet d864512631 Fix flaky test 2016-10-01 00:37:21 -07:00
Sean 6ee5d61c91 HDF5Matrix documentation (#3931) 2016-10-01 00:14:39 -07:00
fchollet 04df170bea Merge branch 'master' of ssh://github.com/fchollet/keras 2016-10-01 00:11:45 -07:00
fchollet 5f58a6d2ca Support all backends, dim orderings for music CRNN 2016-10-01 00:11:39 -07:00
Yu Yin ffff5e99aa Fix summary param counting problem (#3661) (#3884)
* Fix summary param counting problem (#3661)

* ...recursively

* Fix default parameter
2016-09-30 22:15:10 -07:00
Francois Chollet 8fab33c245 Make deconv VAE compatible with both dim orderings 2016-09-30 16:26:50 -07:00
Eder Santana 3bf8964355 Keras is TF first. Fix TH first example (#3914)
* Keras is TF first. Fix TH first example

* Use K.set_image_dim_ordering('th')
2016-09-29 10:57:08 -07:00
JM Arbona a3697d097d Added recurrent convolutionnal layer 2016-09-29 10:18:24 +02:00
Thomas Boquet 51c85dd8d6 Bypass shape inference in deconv2d and use the output shape provided by the user (#3838)
* bypass shape inference in deconv2d

* * more doc in deconv layer

* more deconv layers in var autoencoder example

* * typo doc

* replicate deconv example with with paper's params

* replicate example with paper's params

* typo doc

* + relus in the deconv

* typo in var autoencodeur example

* + mult by ndim

* style fixes

* pep8
2016-09-28 13:40:44 -07:00
Nithish deva Divakar 31f41b9822 typos (#3869)
Added missing numpy imports in examples
2016-09-28 12:30:36 -07:00
M Clark 458576bbe7 List files in alphabetical order (#3871)
`os.listdir` to `sorted(os.listdir)` for alphabetical order instead of arbitrary order. Following PR#3751 this allows mask and images with the same name to be read together.
2016-09-28 12:30:21 -07:00
Yu Yin e3a64cc8a7 Choose format according to filename when plotting (#3883) 2016-09-28 11:43:23 -07:00
Francois Chollet 9045616bda Revert adadelta lr 2016-09-27 10:50:35 -07:00
Francois Chollet 25dbe8097f Update adadelta default learning rate 2016-09-27 09:56:58 -07:00
fchollet fb6a2941b9 Fix typos 2016-09-24 22:19:32 -07:00
fchollet ed131973ef Fix music tagger application 2016-09-24 22:12:22 -07:00
Keunwoo Choi 43060d8c7d add audio models: audio_convnet and audio_conv_rnn (#3718)
* add audio models: audio_convnet and audio_conv_rnn

* add audio models: audio_convnet and audio_conv_rnn

* remove white spaces at the end of lines

* add audio_conv_utils.py, update applications.md

* remove useless line in example in application.md

* remove useless line in example in application.md

* rename models (MusicTaggerCNN,CRNN), BN mode=0 weights

* pep8

* remove MusicTaggerCNN, add include_top argument

* update to follow pep8
2016-09-24 19:53:47 -07:00
fchollet d5f1250a8b Update imagenet prediction decoding utilities 2016-09-24 11:46:41 -07:00
Bas Veeling 4c01c0c4d7 ReduceLROnPlateau Callback and CSVLogger Callback (#3780)
* ReduceLROnPlateau Callback and CSVLogger Callback

* Added documentation and cleanup.

* Added examples.

* Added test for ReduceLROnPlateau()

* Minor changes to naming.

* Added epsilon for lr comparison.

* Fix sensitivity issue

* PEP8
2016-09-23 21:16:19 -07:00
danstowell af28101af1 Functional API guide: fix variable names "loss"->"output" (#3856)
Some of the variable names in this guide were misleadingly named. The outputs were named as `*_loss` implying that they held loss values, whereas they in fact held the outputs. It rather confused me; I believe my proposed naming is clearer.
2016-09-23 08:59:36 -07:00
Flynn, Michael D 56aa9f364a Add cropping layers to documentation (#3853)
* Correct documentation for Cropping3D layer

* Add Cropping layers to documentation
2016-09-22 20:46:22 -07:00
Taras Boiko f0d9867d09 Changed ELU implementation to use native ops (#3845) 2016-09-22 11:08:21 -07:00
Carl Thomé cfc9b4d41d LambdaCallback (#3760)
* Added optional path argument

* Added optional field name argument

* Added LambdaCallback callback

* Fixed on_epoch_begin assignment

* Match default signatures

* Whitespace

* Test LambdaCallback examples

* Only test process termination

* Imports

* Fixed test

* Wait on process to terminate
2016-09-22 09:19:51 -07:00
Fariz Rahman de66211afb Set theano as default backend for windows users (#3831)
* Set theano as default backend for windows users

* Update __init__.py
2016-09-21 21:12:06 -07:00
M Clark 414d5f0978 make ImageDataGenerator behaviour fully seedable/repeatable (#3751)
* make ImageDataGenerator behaviour fully seedable/repeatable

This makes ImageDataGenerator fully seedable.
- the seed argument in fit is now used
- the seed argument in flow and flow_from_directory now effects
transforms
- added example to docs of transforming images and masks together
- added test of using two seeded streams at once

* implemented requested changes

- PEP8
- explicit names
- classes=None
- remove test
2016-09-21 21:11:39 -07:00
Fariz Rahman 99bd066f38 TimeDistributed : unroll RNN when using TF backend (#3835)
* TimeDistributed : unroll RNN when using TF backend

TF dynamic rnn not working with ndim > 3

* Update wrappers.py

* Update wrappers.py
2016-09-21 17:31:46 -07:00
ηzw 82a22b20fc Update default dim_ordering (#3832)
* Update default dim_ordering

* Update default dim_ordering
2016-09-21 11:32:08 -07:00
Francois Chollet 25ed701dbd Merge branch 'master' of https://github.com/fchollet/keras 2016-09-20 21:40:07 -07:00
Francois Chollet 875c521413 Update deep dream example 2016-09-20 21:39:51 -07:00
kuza55 7b8363632e Attempted fix for #3801 (#3827) 2016-09-20 14:57:08 -07:00
kuza55 06f18fa1b9 Matthews Correlation fix and test (#3822) 2016-09-20 09:19:00 -07:00
Taras Boiko 54fc646537 Split multitest in test_recurrent (#3818) 2016-09-20 08:43:42 -07:00
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
122 arquivos alterados com 11811 adições e 4756 exclusões
+10 -10
Ver Arquivo
@@ -3,18 +3,18 @@ dist: trusty
language: python
matrix:
include:
- python: 3.4
env: KERAS_BACKEND=theano
- python: 3.4
env: KERAS_BACKEND=tensorflow
- python: 2.7
env: KERAS_BACKEND=theano
- python: 2.7
env: KERAS_BACKEND=tensorflow
env: KERAS_BACKEND=theano TEST_MODE=PEP8
- python: 2.7
env: KERAS_BACKEND=theano TEST_MODE=INTEGRATION_TESTS
- python: 2.7
env: KERAS_BACKEND=theano TEST_MODE=PEP8
env: KERAS_BACKEND=tensorflow
- python: 3.4
env: KERAS_BACKEND=tensorflow
- python: 2.7
env: KERAS_BACKEND=theano
- python: 3.4
env: KERAS_BACKEND=theano
install:
# code below is taken from http://conda.pydata.org/docs/travis.html
# We do this conditionally because it saves us some downloading if the
@@ -49,9 +49,9 @@ install:
# install TensorFlow
- if [[ "$TRAVIS_PYTHON_VERSION" == "2.7" ]]; then
pip install https://storage.googleapis.com/tensorflow/linux/cpu/tensorflow-0.9.0-cp27-none-linux_x86_64.whl;
pip install https://storage.googleapis.com/tensorflow/linux/cpu/tensorflow-0.11.0-cp27-none-linux_x86_64.whl;
elif [[ "$TRAVIS_PYTHON_VERSION" == "3.4" ]]; then
pip install https://storage.googleapis.com/tensorflow/linux/cpu/tensorflow-0.9.0-cp34-cp34m-linux_x86_64.whl;
pip install https://storage.googleapis.com/tensorflow/linux/cpu/tensorflow-0.11.0-cp34-cp34m-linux_x86_64.whl;
fi
# command to run tests
script:
+6 -2
Ver Arquivo
@@ -1,9 +1,13 @@
Please make sure that the boxes below are checked before you submit your issue. Thank you!
Please make sure that the boxes below are checked before you submit your issue. If your issue is an implementation question, please ask your question on [StackOverflow](http://stackoverflow.com/questions/tagged/keras) or [join the Keras Slack channel](https://keras-slack-autojoin.herokuapp.com/) and ask there instead of filing a GitHub issue.
Thank you!
- [ ] Check that you are up-to-date with the master branch of Keras. You can update with:
pip install git+git://github.com/fchollet/keras.git --upgrade --no-deps
- [ ] If running on TensorFlow, check that you are up-to-date with the latest version. The installation instructions can be found [here](https://www.tensorflow.org/get_started/os_setup).
- [ ] If running on Theano, check that you are up-to-date with the master branch of Theano. You can update with:
pip install git+git://github.com/Theano/Theano.git --upgrade --no-deps
- [ ] Provide a link to a GitHub Gist of a Python script that can reproduce your issue (or just copy the script here if it is short).
- [ ] Provide a link to a GitHub Gist of a Python script that can reproduce your issue (or just copy the script here if it is short).
+19 -15
Ver Arquivo
@@ -1,19 +1,19 @@
# 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)
## 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 high-level 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 +114,17 @@ 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
@@ -137,18 +138,21 @@ 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.
------------------
## Support
You can ask questions and join the development discussion on the [Keras Google group](https://groups.google.com/forum/#!forum/keras-users).
You can ask questions and join the development discussion:
You can also post bug reports and feature requests in [Github issues](https://github.com/fchollet/keras/issues). Make sure to read [our guidelines](https://github.com/fchollet/keras/blob/master/CONTRIBUTING.md) first.
- On the [Keras Google group](https://groups.google.com/forum/#!forum/keras-users).
- On the [Keras Slack channel](https://kerasteam.slack.com). Use [this link](https://keras-slack-autojoin.herokuapp.com/) to request an invitation to the channel.
You can also post **bug reports and feature requests** (only) in [Github issues](https://github.com/fchollet/keras/issues). Make sure to read [our guidelines](https://github.com/fchollet/keras/blob/master/CONTRIBUTING.md) first.
------------------
+4 -4
Ver Arquivo
@@ -1,4 +1,4 @@
FROM nvidia/cuda:7.5-cudnn5-devel
FROM nvidia/cuda:8.0-cudnn5-devel
ENV CONDA_DIR /opt/conda
ENV PATH $CONDA_DIR/bin:$PATH
@@ -24,10 +24,10 @@ RUN useradd -m -s /bin/bash -N -u $NB_UID $NB_USER && \
USER keras
# Python
ARG python_version=3.5.1
ARG tensorflow_version=0.9.0rc0-cp35-cp35m
ARG python_version=3.5.2
ARG tensorflow_version=0.12.0rc0-cp35-cp35m
RUN conda install -y python=${python_version} && \
pip install https://storage.googleapis.com/tensorflow/linux/gpu/tensorflow-${tensorflow_version}-linux_x86_64.whl && \
pip install https://storage.googleapis.com/tensorflow/linux/gpu/tensorflow_gpu-${tensorflow_version}-linux_x86_64.whl && \
pip install git+git://github.com/Theano/Theano.git && \
pip install ipdb pytest pytest-cov python-coveralls coverage==3.7.1 pytest-xdist pep8 pytest-pep8 pydot_ng && \
conda install Pillow scikit-learn notebook pandas matplotlib nose pyyaml six h5py && \
+50 -8
Ver Arquivo
@@ -40,6 +40,7 @@ Index
Sequence preprocessing
Objectives
Metrics
Optimizers
Activations
Callbacks
@@ -65,6 +66,7 @@ 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
@@ -78,10 +80,15 @@ from keras import callbacks
from keras import models
from keras.engine import topology
from keras import objectives
from keras import metrics
from keras import backend
from keras import constraints
from keras import activations
from keras import regularizers
from keras.utils import data_utils
from keras.utils import io_utils
from keras.utils import layer_utils
from keras.utils import np_utils
EXCLUDE = {
@@ -132,6 +139,9 @@ PAGES = [
core.Dense,
core.Activation,
core.Dropout,
core.SpatialDropout1D,
core.SpatialDropout2D,
core.SpatialDropout3D,
core.Flatten,
core.Reshape,
core.Permute,
@@ -149,11 +159,15 @@ PAGES = [
'page': 'layers/convolutional.md',
'classes': [
convolutional.Convolution1D,
convolutional.AtrousConvolution1D,
convolutional.Convolution2D,
convolutional.AtrousConvolution2D,
convolutional.SeparableConvolution2D,
convolutional.Deconvolution2D,
convolutional.Convolution3D,
convolutional.Cropping1D,
convolutional.Cropping2D,
convolutional.Cropping3D,
convolutional.UpSampling1D,
convolutional.UpSampling2D,
convolutional.UpSampling3D,
@@ -165,12 +179,16 @@ 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,
],
},
{
@@ -213,8 +231,10 @@ PAGES = [
'page': 'layers/wrappers.md',
'all_module_classes': [wrappers],
},
{
'page': 'metrics.md',
'all_module_functions': [metrics],
},
{
'page': 'optimizers.md',
'all_module_classes': [optimizers],
@@ -227,6 +247,28 @@ PAGES = [
'page': 'backend.md',
'all_module_functions': [backend],
},
{
'page': 'utils/data_utils.md',
'functions': [
data_utils.get_file,
]
},
{
'page': 'utils/io_utils.md',
'classes': [
io_utils.HDF5Matrix
],
},
{
'page': 'utils/layer_utils.md',
'functions': [
layer_utils.layer_from_config,
]
},
{
'page': 'utils/np_utils.md',
'all_module_functions': [np_utils]
},
]
ROOT = 'http://keras.io/'
+8 -1
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
@@ -37,17 +38,23 @@ pages:
- Text Preprocessing: preprocessing/text.md
- Image Preprocessing: preprocessing/image.md
- Objectives: objectives.md
- Metrics: metrics.md
- Optimizers: optimizers.md
- Activations: activations.md
- Callbacks: callbacks.md
- Datasets: datasets.md
- Applications: applications.md
- Backend: backend.md
- Initializations: initializations.md
- Regularizers: regularizers.md
- Constraints: constraints.md
- Visualization: visualization.md
- Scikit-learn API: scikit-learn-api.md
- Utils:
- Data Utils: utils/data_utils.md
- I/O Utils: utils/io_utils.md
- Layer Utils: utils/layer_utils.md
- Numpy Utils: utils/np_utils.md
+451
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@@ -0,0 +1,451 @@
# 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:
- [Xception](#xception)
- [VGG16](#vgg16)
- [VGG19](#vgg19)
- [ResNet50](#resnet50)
- [InceptionV3](#inceptionv3)
All of these architectures (except Xception) 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".
The Xception model is only available for TensorFlow, due to its reliance on `SeparableConvolution` layers.
### Model for music audio file auto-tagging (taking as input Mel-spectrograms):
- [MusicTaggerCRNN](#musictaggercrnn)
-----
## Usage examples for image classification models
### 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
import numpy as np
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)
# decode the results into a list of tuples (class, description, probability)
# (one such list for each sample in the batch)
print('Predicted:', decode_predictions(preds, top=3)[0])
# Predicted: [(u'n02504013', u'Indian_elephant', 0.82658225), (u'n01871265', u'tusker', 0.1122357), (u'n02504458', u'African_elephant', 0.061040461)]
```
### Extract features with VGG16
```python
from keras.applications.vgg16 import VGG16
from keras.preprocessing import image
from keras.applications.vgg16 import preprocess_input
import numpy as np
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
import numpy as np
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)
```
-----
# Documentation for individual models
- [Xception](#xception)
- [VGG16](#vgg16)
- [VGG19](#vgg19)
- [ResNet50](#resnet50)
- [InceptionV3](#inceptionv3)
- [MusicTaggerCRNN](#musictaggercrnn)
-----
## Xception
```python
keras.applications.xception.Xception(include_top=True, weights='imagenet', input_tensor=None, input_shape=None)
```
Xception V1 model, with weights pre-trained on ImageNet.
On ImageNet, this model gets to a top-1 validation accuracy of 0.790
and a top-5 validation accuracy of 0.945.
Note that this model is only available for the TensorFlow backend,
due to its reliance on `SeparableConvolution` layers. Additionally it only supports
the dimension ordering "tf" (width, height, channels).
The default input size for this model is 299x299.
### Arguments
- include_top: whether to include the fully-connected layer 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.
- inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(299, 299, 3)`.
It should have exactly 3 inputs channels,
and width and height should be no smaller than 71.
E.g. `(150, 150, 3)` would be one valid value.
### Returns
A Keras model instance.
### References
- [Xception: Deep Learning with Depthwise Separable Convolutions](https://arxiv.org/abs/1610.02357)
### License
These weights are trained by ourselves and are released under the MIT license.
-----
## VGG16
```python
keras.applications.vgg16.VGG16(include_top=True, weights='imagenet', input_tensor=None, input_shape=None)
```
VGG16 model, with weights pre-trained on ImageNet.
This model is available for both the Theano and TensorFlow backend, and can be built both
with "th" dim ordering (channels, width, height) or "tf" dim ordering (width, height, channels).
The default input size for this model is 224x224.
### 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.
- inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(224, 224, 3)` (with `tf` dim ordering)
or `(3, 224, 244)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 48.
E.g. `(200, 200, 3)` would be one valid value.
### 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, input_shape=None)
```
VGG19 model, with weights pre-trained on ImageNet.
This model is available for both the Theano and TensorFlow backend, and can be built both
with "th" dim ordering (channels, width, height) or "tf" dim ordering (width, height, channels).
The default input size for this model is 224x224.
### 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.
- inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(224, 224, 3)` (with `tf` dim ordering)
or `(3, 224, 244)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 48.
E.g. `(200, 200, 3)` would be one valid value.
### 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, input_shape=None)
```
ResNet50 model, with weights pre-trained on ImageNet.
This model is available for both the Theano and TensorFlow backend, and can be built both
with "th" dim ordering (channels, width, height) or "tf" dim ordering (width, height, channels).
The default input size for this model is 224x224.
### Arguments
- include_top: whether to include the fully-connected layer 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.
- inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(224, 224, 3)` (with `tf` dim ordering)
or `(3, 224, 244)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 197.
E.g. `(200, 200, 3)` would be one valid value.
### 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, input_shape=None)
```
Inception V3 model, with weights pre-trained on ImageNet.
This model is available for both the Theano and TensorFlow backend, and can be built both
with "th" dim ordering (channels, width, height) or "tf" dim ordering (width, height, channels).
The default input size for this model is 299x299.
### Arguments
- include_top: whether to include the fully-connected layer 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.
- inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(299, 299, 3)` (with `tf` dim ordering)
or `(3, 299, 299)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 139.
E.g. `(150, 150, 3)` would be one valid value.
### 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.
-----
## MusicTaggerCRNN
```python
keras.applications.music_tagger_crnn.MusicTaggerCRNN(weights='msd', input_tensor=None, include_top=True)
```
A convolutional-recurrent model taking as input a vectorized representation of the MelSpectrogram of a music track and capable of outputting the musical genre of the track. You can use `keras.applications.music_tagger_crnn.preprocess_input` to convert a sound file to a vectorized spectrogram. This requires to have installed the [Librosa](http://librosa.github.io/librosa/) library. See [the usage example](#music-tagging-and-feature-extraction-with-musictaggercrnn).
### Arguments
- weights: one of `None` (random initialization) or "msd" (pre-training on [Million Song Dataset](http://labrosa.ee.columbia.edu/millionsong/)).
- input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model.
- include_top: whether to include the 1 fully-connected layer (output layer) at the top of the network. If False, the network outputs 32-dim features.
### Returns
A Keras model instance.
### References
- [Convolutional Recurrent Neural Networks for Music Classification](https://arxiv.org/abs/1609.04243)
### License
These weights are ported from the ones [released by Keunwoo Choi](https://github.com/keunwoochoi/music-auto_tagging-keras) under the [MIT license](https://github.com/keunwoochoi/music-auto_tagging-keras/blob/master/LICENSE.md).
### Examples: music tagging and audio feature extraction
```python
from keras.applications.music_tagger_crnn import MusicTaggerCRNN
from keras.applications.music_tagger_crnn import preprocess_input, decode_predictions
import numpy as np
# 1. Tagging
model = MusicTaggerCRNN(weights='msd')
audio_path = 'audio_file.mp3'
melgram = preprocess_input(audio_path)
melgrams = np.expand_dims(melgram, axis=0)
preds = model.predict(melgrams)
print('Predicted:')
print(decode_predictions(preds))
# print: ('Predicted:', [[('rock', 0.097071797), ('pop', 0.042456303), ('alternative', 0.032439161), ('indie', 0.024491295), ('female vocalists', 0.016455274)]])
#. 2. Feature extraction
model = MusicTaggerCRNN(weights='msd', include_top=False)
audio_path = 'audio_file.mp3'
melgram = preprocess_input(audio_path)
melgrams = np.expand_dims(melgram, axis=0)
feats = model.predict(melgrams)
print('Features:')
print(feats[0, :10])
# print: ('Features:', [-0.19160545 0.94259131 -0.9991011 0.47644514 -0.19089699 0.99033844 0.1103896 -0.00340496 0.14823607 0.59856361])
```
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@@ -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.
@@ -29,13 +38,35 @@ 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
```
----
## keras.json details
```
{
"image_dim_ordering": "tf",
"epsilon": 1e-07,
"floatx": "float32",
"backend": "tensorflow"
}
```
You can change these settings by editing `~/.keras/keras.json`.
* `image_dim_ordering`: string, either `"tf"` or `"th"`. It specifies which dimension ordering convention Keras will follow. (`keras.backend.image_dim_ordering()` returns it.)
- For 2D data (e.g. image), `"tf"` assumes `(rows, cols, channels)` while `"th"` assumes `(channels, rows, cols)`.
- For 3D data, `"tf"` assumes `(conv_dim1, conv_dim2, conv_dim3, channels)` while `"th"` assumes `(channels, conv_dim1, conv_dim2, conv_dim3)`.
* `epsilon`: float, a numeric fuzzing constant used to avoid dividing by zero in some operations.
* `floatx`: string, `"float16"`, `"float32"`, or `"float64"`. Default float precision.
* `backend`: string, `"tensorflow"` or `"theano"`.
----
## Using the abstract Keras backend to write new code
If you want the Keras modules you write to be compatible with both Theano and TensorFlow, you have to write them via the abstract Keras backend API. Here's an intro.
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@@ -2,7 +2,7 @@
Functions from the `constraints` module allow setting constraints (eg. non-negativity) on network parameters during optimization.
The penalties are applied on a per-layer basis. The exact API will depend on the layer, but the layers `Dense`, `TimeDistributedDense`, `MaxoutDense`, `Convolution1D` and `Convolution2D` have a unified API.
The penalties are applied on a per-layer basis. The exact API will depend on the layer, but the layers `Dense`, `TimeDistributedDense`, `MaxoutDense`, `Convolution1D`, `Convolution2D` and `Convolution3D` have a unified API.
These layers expose 2 keyword arguments:
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@@ -4,7 +4,7 @@
- [How can I run Keras on GPU?](#how-can-i-run-keras-on-gpu)
- [How can I save a Keras model?](#how-can-i-save-a-keras-model)
- [Why is the training loss much higher than the testing loss?](#why-is-the-training-loss-much-higher-than-the-testing-loss)
- [How can I visualize the output of an intermediate layer?](#how-can-i-visualize-the-output-of-an-intermediate-layer)
- [How can I obtain the output of an intermediate layer?](#how-can-i-obtain-the-output-of-an-intermediate-layer)
- [How can I use Keras with datasets that don't fit in memory?](#how-can-i-use-keras-with-datasets-that-dont-fit-in-memory)
- [How can I interrupt training when the validation loss isn't decreasing anymore?](#how-can-i-interrupt-training-when-the-validation-loss-isnt-decreasing-anymore)
- [How is the validation split computed?](#how-is-the-validation-split-computed)
@@ -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?
@@ -129,9 +156,22 @@ Besides, the training loss is the average of the losses over each batch of train
---
### How can I visualize the output of an intermediate layer?
### How can I obtain the output of an intermediate layer?
You can build a Keras function that will return the output of a certain layer given a certain input, for example:
One simple way is to create a new `Model` that will output the layers that you are interested in:
```python
from keras.models import Model
model = ... # create the original model
layer_name = 'my_layer'
intermediate_layer_model = Model(input=model.input,
output=model.get_layer(layer_name).output)
intermediate_output = intermediate_layer_model.predict(data)
```
Alternatively, you can build a Keras function that will return the output of a certain layer given a certain input, for example:
```python
from keras import backend as K
@@ -158,22 +198,6 @@ layer_output = get_3rd_layer_output([X, 0])[0]
layer_output = get_3rd_layer_output([X, 1])[0]
```
Another more flexible way of getting output from intermediate layers is to use the [functional API](/getting-started/functional-api-guide). For example, if you have created an autoencoder for MNIST:
```python
inputs = Input(shape=(784,))
encoded = Dense(32, activation='relu')(inputs)
decoded = Dense(784)(encoded)
model = Model(input=inputs, output=decoded)
```
After compiling and training the model, you can get the output of the data from the encoder like this:
```python
encoder = Model(input=inputs, output=encoded)
X_encoded = encoder.predict(X)
```
---
### How can I use Keras with datasets that don't fit in memory?
@@ -202,8 +226,9 @@ Find out more in the [callbacks documentation](/callbacks).
### How is the validation split computed?
If you set the `validation_split` argument in `model.fit` to e.g. 0.1, then the validation data used will be the *last 10%* of the data. If you set it to 0.25, it will be the last 25% of the data, etc.
If you set the `validation_split` argument in `model.fit` to e.g. 0.1, then the validation data used will be the *last 10%* of the data. If you set it to 0.25, it will be the last 25% of the data, etc. Note that the data isn't shuffled before extracting the validation split, so the validation is literally just the *last* x% of samples in the input you passed.
The same validation set is used for all epochs (within a same call to `fit`).
---
@@ -336,9 +361,20 @@ 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:
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@@ -102,7 +102,7 @@ lstm_out = LSTM(32)(x)
Here we insert the auxiliary loss, allowing the LSTM and Embedding layer to be trained smoothly even though the main loss will be much higher in the model.
```python
auxiliary_loss = Dense(1, activation='sigmoid', name='aux_output')(lstm_out)
auxiliary_output = Dense(1, activation='sigmoid', name='aux_output')(lstm_out)
```
At this point, we feed into the model our auxiliary input data by concatenating it with the LSTM output:
@@ -117,13 +117,13 @@ x = Dense(64, activation='relu')(x)
x = Dense(64, activation='relu')(x)
# and finally we add the main logistic regression layer
main_loss = Dense(1, activation='sigmoid', name='main_output')(x)
main_output = Dense(1, activation='sigmoid', name='main_output')(x)
```
This defines a model with two inputs and two outputs:
```python
model = Model(input=[main_input, auxiliary_input], output=[main_loss, auxiliary_loss])
model = Model(input=[main_input, auxiliary_input], output=[main_output, auxiliary_output])
```
We compile the model and assign a weight of 0.2 to the auxiliary loss.
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@@ -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).
@@ -121,7 +121,7 @@ Before training a model, you need to configure the learning process, which is do
- an optimizer. This could be the string identifier of an existing optimizer (such as `rmsprop` or `adagrad`), or an instance of the `Optimizer` class. See: [optimizers](/optimizers).
- a loss function. This is the objective that the model will try to minimize. It can be the string identifier of an existing loss function (such as `categorical_crossentropy` or `mse`), or it can be an objective function. See: [objectives](/objectives).
- a list of metrics. For any classification problem you will want to set this to `metrics=['accuracy']`. A metric could be the string identifier of an existing metric (only `accuracy` is supported at this point), or a custom metric function.
- a list of metrics. For any classification problem you will want to set this to `metrics=['accuracy']`. A metric could be the string identifier of an existing metric or a custom metric function. Custom metric function should return either a single tensor value or a dict `metric_name -> metric_value`. See: [metrics](/metrics).
```python
# for a multi-class classification problem
@@ -137,6 +137,24 @@ model.compile(optimizer='rmsprop',
# for a mean squared error regression problem
model.compile(optimizer='rmsprop',
loss='mse')
# for custom metrics
import keras.backend as K
def mean_pred(y_true, y_pred):
return K.mean(y_pred)
def false_rates(y_true, y_pred):
false_neg = ...
false_pos = ...
return {
'false_neg': false_neg,
'false_pos': false_pos,
}
model.compile(optimizer='rmsprop',
loss='binary_crossentropy',
metrics=['accuracy', mean_pred, false_rates])
```
----
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@@ -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 high-level 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.
------------------
@@ -110,41 +110,45 @@ 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.
------------------
## Support
You can ask questions and join the development discussion on the [Keras Google group](https://groups.google.com/forum/#!forum/keras-users).
You can ask questions and join the development discussion:
You can also post bug reports and feature requests in [Github issues](https://github.com/fchollet/keras/issues). Make sure to read [our guidelines](https://github.com/fchollet/keras/blob/master/CONTRIBUTING.md) first.
- On the [Keras Google group](https://groups.google.com/forum/#!forum/keras-users).
- On the [Keras Slack channel](https://kerasteam.slack.com). Use [this link](https://keras-slack-autojoin.herokuapp.com/) to request an invitation to the channel.
You can also post **bug reports and feature requests** (only) in [Github issues](https://github.com/fchollet/keras/issues). Make sure to read [our guidelines](https://github.com/fchollet/keras/blob/master/CONTRIBUTING.md) first.
------------------
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@@ -2,9 +2,9 @@
For simple, stateless custom operations, you are probably better off using `layers.core.Lambda` layers. But for any custom operation that has trainable weights, you should implement your own layer.
Here is the skeleton of a Keras layer. There are only three methods you need to implement:
Here is the skeleton of a Keras layer, **as of Keras 1.1.3** (if you have an older version, please upgrade). There are only three methods you need to implement:
- `build(input_shape)`: this is where you will define your weights. Trainable weights should be added to the list `self.trainable_weights`. Other attributes of note are: `self.non_trainable_weights` (list) and `self.updates` (list of update tuples (tensor, new_tensor)). For an example of how to use `non_trainable_weights` and `updates`, see the code for the `BatchNormalization` layer.
- `build(input_shape)`: this is where you will define your weights. This method must set `self.built = True`, which can be done by calling `super([Layer], self).build()`.
- `call(x)`: this is where the layer's logic lives. Unless you want your layer to support masking, you only have to care about the first argument passed to `call`: the input tensor.
- `get_output_shape_for(input_shape)`: in case your layer modifies the shape of its input, you should specify here the shape transformation logic. This allows Keras to do automatic shape inference.
@@ -19,10 +19,11 @@ class MyLayer(Layer):
super(MyLayer, self).__init__(**kwargs)
def build(self, input_shape):
input_dim = input_shape[1]
initial_weight_value = np.random.random((input_dim, output_dim))
self.W = K.variable(initial_weight_value)
self.trainable_weights = [self.W]
# Create a trainable weight variable for this layer.
self.W = self.add_weight(shape=(input_shape[1], self.output_dim),
initializer='random_uniform',
trainable=True)
super(MyLayer, self).build() # Be sure to call this somewhere!
def call(self, x, mask=None):
return K.dot(x, self.W)
@@ -31,4 +32,4 @@ class MyLayer(Layer):
return (input_shape[0], self.output_dim)
```
The existing Keras layers provide ample examples of how to implement almost anything. Never hesitate to read the source code!
The existing Keras layers provide ample examples of how to implement almost anything. Never hesitate to read the source code!
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@@ -0,0 +1,51 @@
## Usage of metrics
A metric is a function that is used to judge the performance of your model. Metric functions are to be supplied in the `metrics` parameter when a model is compiled.
A metric function is similar to an [objective function](/objectives), except that the results from evaluating a metric are not used when training the model.
You can either pass the name of an existing metric, or pass a Theano/TensorFlow symbolic function (see [Custom metrics](#custom-metrics)).
#### Arguments
- __y_true__: True labels. Theano/TensorFlow tensor.
- __y_pred__: Predictions. Theano/TensorFlow tensor of the same shape as y_true.
#### Returns
Single tensor value representing the mean of the output array across all
datapoints.
----
## Available metrics
{{autogenerated}}
----
## Custom metrics
Custom metrics can be defined and passed via the compilation step. The
function would need to take `(y_true, y_pred)` as arguments and return
either a single tensor value or a dict `metric_name -> metric_value`.
```python
# for custom metrics
import keras.backend as K
def mean_pred(y_true, y_pred):
return K.mean(y_pred)
def false_rates(y_true, y_pred):
false_neg = ...
false_pos = ...
return {
'false_neg': false_neg,
'false_pos': false_pos,
}
model.compile(optimizer='rmsprop',
loss='binary_crossentropy',
metrics=['accuracy', mean_pred, false_rates])
```
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@@ -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.
+8
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@@ -30,3 +30,11 @@ For a few examples of such functions, check out the [objectives source](https://
- __kullback_leibler_divergence__ / __kld__: Information gain from a predicted probability distribution Q to a true probability distribution P. Gives a measure of difference between both distributions.
- __poisson__: Mean of `(predictions - targets * log(predictions))`
- __cosine_proximity__: The opposite (negative) of the mean cosine proximity between predictions and targets.
**Note**: when using the `categorical_crossentropy` objective, your targets should be in categorical format (e.g. if you have 10 classes, the target for each sample should be a 10-dimensional vector that is all-zeros expect for a 1 at the index corresponding to the class of the sample). In order to convert *integer targets* into *categorical targets*, you can use the Keras utility `to_categorical`:
```python
from keras.utils.np_utils import to_categorical
categorical_labels = to_categorical(int_labels, nb_classes=None)
```
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@@ -24,9 +24,9 @@ keras.preprocessing.image.ImageDataGenerator(featurewise_center=False,
Generate batches of tensor image data with real-time data augmentation. The data will be looped over (in batches) indefinitely.
- __Arguments__:
- __featurewise_center__: Boolean. Set input mean to 0 over the dataset.
- __featurewise_center__: Boolean. Set input mean to 0 over the dataset, feature-wise.
- __samplewise_center__: Boolean. Set each sample mean to 0.
- __featurewise_std_normalization__: Boolean. Divide inputs by std of the dataset.
- __featurewise_std_normalization__: Boolean. Divide inputs by std of the dataset, feature-wise.
- __samplewise_std_normalization__: Boolean. Divide each input by its std.
- __zca_whitening__: Boolean. Apply ZCA whitening.
- __rotation_range__: Int. Degree range for random rotations.
@@ -43,44 +43,54 @@ Generate batches of tensor image data with real-time data augmentation. The data
otherwise we multiply the data by the value provided (before applying
any other transformation).
- __dim_ordering__: One of {"th", "tf"}.
"tf" mode means that the images should have shape `(samples, width, height, channels)`,
"th" mode means that the images should have shape `(samples, channels, width, height)`.
"tf" mode means that the images should have shape `(samples, height, width, channels)`,
"th" mode means that the images should have shape `(samples, channels, height, width)`.
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".
If you never set it, then it will be "tf".
- __Methods__:
- __fit(X)__: Compute the internal data stats related to the data-dependent transformations, based on an array of sample data.
Only required if featurewise_center or featurewise_std_normalization or zca_whitening.
- __Arguments__:
- __X__: sample data.
- __X__: sample data. Should have rank 4.
In case of grayscale data,
the channels axis should have value 1, and in case
of RGB data, it should have value 3.
- __augment__: Boolean (default: False). Whether to fit on randomly augmented samples.
- __rounds__: int (default: 1). If augment, how many augmentation passes over the data to use.
- __seed__: int (default: None). Random seed.
- __flow(X, y)__: Takes numpy data & label arrays, and generates batches of augmented/normalized data. Yields batches indefinitely, in an infinite loop.
- __Arguments__:
- __X__: data.
- __X__: data. Should have rank 4.
In case of grayscale data,
the channels axis should have value 1, and in case
of RGB data, it should have value 3.
- __y__: labels.
- __batch_size__: int (default: 32).
- __shuffle__: boolean (defaut: True).
- __seed__: int (default: None).
- __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,
and the subdirectories should contain PNG or JPG images. See [this script](https://gist.github.com/fchollet/0830affa1f7f19fd47b06d4cf89ed44d) for more details.
- __directory__: path to the target directory. It should contain one subdirectory per class.
Any PNG, JPG or BNP images inside each of the subdirectories directory tree will be included in the generator.
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.
- __classes__: optional list of class subdirectories (e.g. `['dogs', 'cats']`). Default: None. If not provided, the list of classes will be automatically inferred (and the order of the classes, which will map to the label indices, will be alphanumeric).
- __class_mode__: one of "categorical", "binary", "sparse" or None. Default: "categorical". Determines the type of label arrays that are returned: "categorical" will be 2D one-hot encoded labels, "binary" will be 1D binary labels, "sparse" will be 1D integer labels. If None, no labels are returned (the generator will only yield batches of image data, which is useful to use `model.predict_generator()`, `model.evaluate_generator()`, etc.).
- __batch_size__: size of the batches of data (default: 32).
- __shuffle__: whether to shuffle the data (default: True)
- __seed__: optional random seed for shuffling.
- __seed__: optional random seed for shuffling and transformations.
- __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. 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".
- __follow_links__: whether to follow symlinks inside class subdirectories (default: False).
- __Examples__:
@@ -151,3 +161,40 @@ model.fit_generator(
validation_data=validation_generator,
nb_val_samples=800)
```
Example of transforming images and masks together.
```python
# we create two instances with the same arguments
data_gen_args = dict(featurewise_center=True,
featurewise_std_normalization=True,
rotation_range=90.,
width_shift_range=0.1,
height_shift_range=0.1,
zoom_range=0.2)
image_datagen = ImageDataGenerator(**data_gen_args)
mask_datagen = ImageDataGenerator(**data_gen_args)
# Provide the same seed and keyword arguments to the fit and flow methods
seed = 1
image_datagen.fit(images, augment=True, seed=seed)
mask_datagen.fit(masks, augment=True, seed=seed)
image_generator = image_datagen.flow_from_directory(
'data/images',
class_mode=None,
seed=seed)
mask_generator = mask_datagen.flow_from_directory(
'data/masks',
class_mode=None,
seed=seed)
# combine generators into one which yields image and masks
train_generator = zip(image_generator, mask_generator)
model.fit_generator(
train_generator,
samples_per_epoch=2000,
nb_epoch=50)
```
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@@ -2,7 +2,7 @@
Regularizers allow to apply penalties on layer parameters or layer activity during optimization. These penalties are incorporated in the loss function that the network optimizes.
The penalties are applied on a per-layer basis. The exact API will depend on the layer, but the layers `Dense`, `TimeDistributedDense`, `MaxoutDense`, `Convolution1D` and `Convolution2D` have a unified API.
The penalties are applied on a per-layer basis. The exact API will depend on the layer, but the layers `Dense`, `TimeDistributedDense`, `MaxoutDense`, `Convolution1D`, `Convolution2D` and `Convolution3D` have a unified API.
These layers expose 3 keyword arguments:
+97
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@@ -0,0 +1,97 @@
# Keras examples directory
[addition_rnn.py](addition_rnn.py)
Implementation of sequence to sequence learning for performing addition of two numbers (as strings).
[antirectifier.py](antirectifier.py)
Demonstrates how to write custom layers for Keras.
[babi_memnn.py](babi_memnn.py)
Trains a memory network on the bAbI dataset for reading comprehension.
[babi_rnn.py](babi_rnn.py)
Trains a two-branch recurrent network on the bAbI dataset for reading comprehension.
[cifar10_cnn.py](cifar10_cnn.py)
Trains a simple deep CNN on the CIFAR10 small images dataset.
[conv_filter_visualization.py](conv_filter_visualization.py)
Visualization of the filters of VGG16, via gradient ascent in input space.
[conv_lstm.py](conv_lstm.py)
Demonstrates the use of a convolutional LSTM network.
[deep_dream.py](deep_dream.py)
Deep Dreams in Keras.
[image_ocr.py](image_ocr.py)
Trains a convolutional stack followed by a recurrent stack and a CTC logloss function to perform optical character recognition (OCR).
[imdb_bidirectional_lstm.py](imdb_bidirectional_lstm.py)
Trains a Bidirectional LSTM on the IMDB sentiment classification task.
[imdb_cnn.py](imdb_cnn.py)
Demonstrates the use of Convolution1D for text classification.
[imdb_cnn_lstm.py](imdb_cnn_lstm.py)
Trains a convolutional stack followed by a recurrent stack network on the IMDB sentiment classification task.
[imdb_fasttext.py](imdb_fasttext.py)
Trains a FastText model on the IMDB sentiment classification task.
[imdb_lstm.py](imdb_lstm.py)
Trains a LSTM on the IMDB sentiment classification task.
[lstm_benchmark.py](lstm_benchmark.py)
Compares different LSTM implementations on the IMDB sentiment classification task.
[lstm_text_generation.py](lstm_text_generation.py)
Generates text from Nietzsche's writings.
[mnist_cnn.py](mnist_cnn.py)
Trains a simple convnet on the MNIST dataset.
[mnist_hierarchical_rnn.py](mnist_hierarchical_rnn.py)
Trains a Hierarchical RNN (HRNN) to classify MNIST digits.
[mnist_irnn.py](mnist_irnn.py)
Reproduction of the IRNN experiment with pixel-by-pixel sequential MNIST in "A Simple Way to Initialize Recurrent Networks of Rectified Linear Units" by Le et al.
[mnist_mlp.py](mnist_mlp.py)
Trains a simple deep multi-layer perceptron on the MNIST dataset.
[mnist_net2net.py](mnist_net2net.py)
Reproduction of the Net2Net experiment with MNIST in "Net2Net: Accelerating Learning via Knowledge Transfer".
[mnist_siamese_graph.py](mnist_siamese_graph.py)
Trains a Siamese multi-layer perceptron on pairs of digits from the MNIST dataset.
[mnist_sklearn_wrapper.py](mnist_sklearn_wrapper.py)
Demonstrates how to use the sklearn wrapper.
[mnist_swwae.py](mnist_swwae.py)
Trains a Stacked What-Where AutoEncoder built on residual blocks on the MNIST dataset.
[mnist_transfer_cnn.py](mnist_transfer_cnn.py)
Transfer learning toy example.
[neural_doodle.py](neural_doodle.py)
Neural doodle.
[neural_style_transfer.py](neural_style_transfer.py)
Neural style transfer.
[pretrained_word_embeddings.py](pretrained_word_embeddings.py)
Loads pre-trained word embeddings (GloVe embeddings) into a frozen Keras Embedding layer, and uses it to train a text classification model on the 20 Newsgroup dataset.
[reuters_mlp.py](reuters_mlp.py)
Trains and evaluate a simple MLP on the Reuters newswire topic classification task.
[stateful_lstm.py](stateful_lstm.py)
Demonstrates how to use stateful RNNs to model long sequences efficiently.
[variational_autoencoder.py](variational_autoencoder.py)
Demonstrates how to build a variational autoencoder.
[variational_autoencoder_deconv.py](variational_autoencoder_deconv.py)
Demonstrates how to build a variational autoencoder with Keras using deconvolution layers.
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@@ -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()
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@@ -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'
+11 -18
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@@ -1,14 +1,10 @@
'''Train a simple deep CNN on the CIFAR10 small images dataset.
GPU run command:
GPU run command with Theano backend (with TensorFlow, the GPU is automatically used):
THEANO_FLAGS=mode=FAST_RUN,device=gpu,floatX=float32 python cifar10_cnn.py
It gets down to 0.65 test logloss in 25 epochs, and down to 0.55 after 50 epochs.
(it's still underfitting at that point, though).
Note: the data was pickled with Python 2, and some encoding issues might prevent you
from loading it in Python 3. You might have to load it in Python 2,
save it in a different format, load it in Python 3 and repickle it.
'''
from __future__ import print_function
@@ -17,7 +13,6 @@ from keras.preprocessing.image import ImageDataGenerator
from keras.models import Sequential
from keras.layers import Dense, Dropout, Activation, Flatten
from keras.layers import Convolution2D, MaxPooling2D
from keras.optimizers import SGD
from keras.utils import np_utils
batch_size = 32
@@ -27,23 +22,23 @@ data_augmentation = True
# input image dimensions
img_rows, img_cols = 32, 32
# the CIFAR10 images are RGB
# The CIFAR10 images are RGB.
img_channels = 3
# the data, shuffled and split between train and test sets
# The data, shuffled and split between train and test sets:
(X_train, y_train), (X_test, y_test) = cifar10.load_data()
print('X_train shape:', X_train.shape)
print(X_train.shape[0], 'train samples')
print(X_test.shape[0], 'test samples')
# convert class vectors to binary class matrices
# Convert class vectors to binary class matrices.
Y_train = np_utils.to_categorical(y_train, nb_classes)
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'))
@@ -64,10 +59,9 @@ model.add(Dropout(0.5))
model.add(Dense(nb_classes))
model.add(Activation('softmax'))
# let's train the model using SGD + momentum (how original).
sgd = SGD(lr=0.01, decay=1e-6, momentum=0.9, nesterov=True)
# Let's train the model using RMSprop
model.compile(loss='categorical_crossentropy',
optimizer=sgd,
optimizer='rmsprop',
metrics=['accuracy'])
X_train = X_train.astype('float32')
@@ -84,8 +78,7 @@ if not data_augmentation:
shuffle=True)
else:
print('Using real-time data augmentation.')
# this will do preprocessing and realtime data augmentation
# This will do preprocessing and realtime data augmentation:
datagen = ImageDataGenerator(
featurewise_center=False, # set input mean to 0 over the dataset
samplewise_center=False, # set each sample mean to 0
@@ -98,11 +91,11 @@ else:
horizontal_flip=True, # randomly flip images
vertical_flip=False) # randomly flip images
# compute quantities required for featurewise normalization
# (std, mean, and principal components if ZCA whitening is applied)
# Compute quantities required for featurewise normalization
# (std, mean, and principal components if ZCA whitening is applied).
datagen.fit(X_train)
# fit the model on the batches generated by datagen.flow()
# Fit the model on the batches generated by datagen.flow().
model.fit_generator(datagen.flow(X_train, Y_train,
batch_size=batch_size),
samples_per_epoch=X_train.shape[0],
+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):
+142
Ver Arquivo
@@ -0,0 +1,142 @@
""" This script demonstrates the use of a convolutional LSTM network.
This network is used to predict the next frame of an artificially
generated movie which contains moving squares.
"""
from keras.models import Sequential
from keras.layers.convolutional import Convolution3D
from keras.layers.convolutional_recurrent import ConvLSTM2D
from keras.layers.normalization import BatchNormalization
import numpy as np
import pylab as plt
# We create a layer which take as input movies of shape
# (n_frames, width, height, channels) and returns a movie
# of identical shape.
seq = Sequential()
seq.add(ConvLSTM2D(nb_filter=40, nb_row=3, nb_col=3,
input_shape=(None, 40, 40, 1),
border_mode='same', return_sequences=True))
seq.add(BatchNormalization())
seq.add(ConvLSTM2D(nb_filter=40, nb_row=3, nb_col=3,
border_mode='same', return_sequences=True))
seq.add(BatchNormalization())
seq.add(ConvLSTM2D(nb_filter=40, nb_row=3, nb_col=3,
border_mode='same', return_sequences=True))
seq.add(BatchNormalization())
seq.add(ConvLSTM2D(nb_filter=40, nb_row=3, nb_col=3,
border_mode='same', return_sequences=True))
seq.add(BatchNormalization())
seq.add(Convolution3D(nb_filter=1, kernel_dim1=1, kernel_dim2=3,
kernel_dim3=3, activation='sigmoid',
border_mode='same', dim_ordering='tf'))
seq.compile(loss='binary_crossentropy', optimizer='adadelta')
# Artificial data generation:
# Generate movies with 3 to 7 moving squares inside.
# The squares are of shape 1x1 or 2x2 pixels,
# which move linearly over time.
# For convenience we first create movies with bigger width and height (80x80)
# and at the end we select a 40x40 window.
def generate_movies(n_samples=1200, n_frames=15):
row = 80
col = 80
noisy_movies = np.zeros((n_samples, n_frames, row, col, 1), dtype=np.float)
shifted_movies = np.zeros((n_samples, n_frames, row, col, 1),
dtype=np.float)
for i in range(n_samples):
# Add 3 to 7 moving squares
n = np.random.randint(3, 8)
for j in range(n):
# Initial position
xstart = np.random.randint(20, 60)
ystart = np.random.randint(20, 60)
# Direction of motion
directionx = np.random.randint(0, 3) - 1
directiony = np.random.randint(0, 3) - 1
# Size of the square
w = np.random.randint(2, 4)
for t in range(n_frames):
x_shift = xstart + directionx * t
y_shift = ystart + directiony * t
noisy_movies[i, t, x_shift - w: x_shift + w,
y_shift - w: y_shift + w, 0] += 1
# Make it more robust by adding noise.
# The idea is that if during inference,
# the value of the pixel is not exactly one,
# we need to train the network to be robust and still
# consider it as a pixel belonging to a square.
if np.random.randint(0, 2):
noise_f = (-1)**np.random.randint(0, 2)
noisy_movies[i, t,
x_shift - w - 1: x_shift + w + 1,
y_shift - w - 1: y_shift + w + 1,
0] += noise_f * 0.1
# Shift the ground truth by 1
x_shift = xstart + directionx * (t + 1)
y_shift = ystart + directiony * (t + 1)
shifted_movies[i, t, x_shift - w: x_shift + w,
y_shift - w: y_shift + w, 0] += 1
# Cut to a 40x40 window
noisy_movies = noisy_movies[::, ::, 20:60, 20:60, ::]
shifted_movies = shifted_movies[::, ::, 20:60, 20:60, ::]
noisy_movies[noisy_movies >= 1] = 1
shifted_movies[shifted_movies >= 1] = 1
return noisy_movies, shifted_movies
# Train the network
noisy_movies, shifted_movies = generate_movies(n_samples=1200)
seq.fit(noisy_movies[:1000], shifted_movies[:1000], batch_size=10,
nb_epoch=300, validation_split=0.05)
# Testing the network on one movie
# feed it with the first 7 positions and then
# predict the new positions
which = 1004
track = noisy_movies[which][:7, ::, ::, ::]
for j in range(16):
new_pos = seq.predict(track[np.newaxis, ::, ::, ::, ::])
new = new_pos[::, -1, ::, ::, ::]
track = np.concatenate((track, new), axis=0)
# And then compare the predictions
# to the ground truth
track2 = noisy_movies[which][::, ::, ::, ::]
for i in range(15):
fig = plt.figure(figsize=(10, 5))
ax = fig.add_subplot(121)
if i >= 7:
ax.text(1, 3, 'Predictions !', fontsize=20, color='w')
else:
ax.text(1, 3, 'Inital trajectory', fontsize=20)
toplot = track[i, ::, ::, 0]
plt.imshow(toplot)
ax = fig.add_subplot(122)
plt.text(1, 3, 'Ground truth', fontsize=20)
toplot = track2[i, ::, ::, 0]
if i >= 2:
toplot = shifted_movies[which][i - 1, ::, ::, 0]
plt.imshow(toplot)
plt.savefig('%i_animate.png' % (i + 1))
+53 -77
Ver Arquivo
@@ -15,17 +15,16 @@ If running on CPU, prefer the TensorFlow backend (much faster).
Example results: http://i.imgur.com/FX6ROg9.jpg
'''
from __future__ import print_function
from scipy.misc import imread, imresize, imsave
from keras.preprocessing.image import load_img, img_to_array
import numpy as np
from scipy.misc import imsave
from scipy.optimize import fmin_l_bfgs_b
import time
import argparse
import h5py
import os
from keras.models import Sequential
from keras.layers import Convolution2D, ZeroPadding2D, MaxPooling2D
from keras.applications import vgg16
from keras import backend as K
from keras.layers import Input
parser = argparse.ArgumentParser(description='Deep Dreams with Keras.')
parser.add_argument('base_image_path', metavar='base', type=str,
@@ -46,14 +45,14 @@ weights_path = 'vgg16_weights.h5'
# some settings we found interesting
saved_settings = {
'bad_trip': {'features': {'conv4_1': 0.05,
'conv4_2': 0.01,
'conv4_3': 0.01},
'bad_trip': {'features': {'block4_conv1': 0.05,
'block4_conv2': 0.01,
'block4_conv3': 0.01},
'continuity': 0.1,
'dream_l2': 0.8,
'jitter': 5},
'dreamy': {'features': {'conv5_1': 0.05,
'conv5_2': 0.02},
'dreamy': {'features': {'block5_conv1': 0.05,
'block5_conv2': 0.02},
'continuity': 0.1,
'dream_l2': 0.02,
'jitter': 0},
@@ -63,73 +62,39 @@ settings = saved_settings['dreamy']
# 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.transpose((2, 0, 1)).astype('float64')
img = load_img(image_path, target_size=(img_width, img_height))
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_width, img_height))
x = x.transpose((1, 2, 0))
else:
x = x.reshape((img_width, img_height, 3))
# Remove zero-center by mean pixel
x[:, :, 0] += 103.939
x[:, :, 1] += 116.779
x[:, :, 2] += 123.68
# 'BGR'->'RGB'
x = x[:, :, ::-1]
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
dream = first_layer.input
if K.image_dim_ordering() == 'th':
img_size = (3, img_width, img_height)
else:
img_size = (img_width, img_height, 3)
# this will contain our generated image
dream = Input(batch_shape=(1,) + img_size)
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 our placeholder
# the model will be loaded with pre-trained ImageNet weights
model = vgg16.VGG16(input_tensor=dream,
weights='imagenet', include_top=False)
print('Model loaded.')
# get the symbolic outputs of each "key" layer (we gave them unique names).
@@ -138,8 +103,16 @@ layer_dict = dict([(layer.name, layer) for layer in model.layers])
# continuity loss util function
def continuity_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_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:])
else:
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:, :])
return K.sum(K.pow(a + b, 1.25))
# define the loss
@@ -151,12 +124,15 @@ for layer_name in settings['features']:
x = layer_dict[layer_name].output
shape = layer_dict[layer_name].output_shape
# we avoid border artifacts by only involving non-border pixels in the loss
loss -= coeff * K.sum(K.square(x[:, :, 2: shape[2]-2, 2: shape[3]-2])) / np.prod(shape[1:])
if K.image_dim_ordering() == 'th':
loss -= coeff * K.sum(K.square(x[:, :, 2: shape[2] - 2, 2: shape[3] - 2])) / np.prod(shape[1:])
else:
loss -= coeff * K.sum(K.square(x[:, 2: shape[1] - 2, 2: shape[2] - 2, :])) / np.prod(shape[1:])
# add continuity loss (gives image local coherence, can result in an artful blur)
loss += settings['continuity'] * continuity_loss(dream) / (3 * img_width * img_height)
loss += settings['continuity'] * continuity_loss(dream) / np.prod(img_size)
# add image L2 norm to loss (prevents pixels from taking very high values, makes image darker)
loss += settings['dream_l2'] * K.sum(K.square(dream)) / (3 * img_width * img_height)
loss += settings['dream_l2'] * K.sum(K.square(dream)) / np.prod(img_size)
# feel free to further modify the loss as you see fit, to achieve new effects...
@@ -171,7 +147,7 @@ else:
f_outputs = K.function([dream], outputs)
def eval_loss_and_grads(x):
x = x.reshape((1, 3, img_width, img_height))
x = x.reshape((1,) + img_size)
outs = f_outputs([x])
loss_value = outs[0]
if len(outs[1:]) == 1:
@@ -215,7 +191,7 @@ for i in range(5):
start_time = time.time()
# add a random jitter to the initial image. This will be reverted at decoding time
random_jitter = (settings['jitter'] * 2) * (np.random.random((3, img_width, img_height)) - 0.5)
random_jitter = (settings['jitter'] * 2) * (np.random.random(img_size) - 0.5)
x += random_jitter
# run L-BFGS for 7 steps
@@ -223,9 +199,9 @@ for i in range(5):
fprime=evaluator.grads, maxfun=7)
print('Current loss value:', min_val)
# decode the dream and save it
x = x.reshape((3, img_width, img_height))
x = x.reshape(img_size)
x -= random_jitter
img = deprocess_image(x)
img = deprocess_image(np.copy(x))
fname = result_prefix + '_at_iteration_%d.png' % i
imsave(fname, img)
end_time = time.time()
+41 -13
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
@@ -107,13 +109,14 @@ def paint_text(text, w, h):
a = np.frombuffer(buf, np.uint8)
a.shape = (h, w, 4)
a = a[:, :, 0] # grab single channel
a /= 255
a = a.astype(np.float32) / 255
a = np.expand_dims(a, 0)
a = speckle(a)
a = image.random_rotation(a, 3 * (w - top_left_x) / w + 1)
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)
@@ -373,7 +396,12 @@ pool_size_1 = 4
pool_size_2 = 2
time_dense_size = 32
rnn_size = 512
time_steps = img_w / (pool_size_1 * pool_size_2)
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))
@@ -383,11 +411,11 @@ img_gen = TextImageGenerator(monogram_file=os.path.join(fdir, 'wordlist_mono_cle
minibatch_size=32,
img_w=img_w,
img_h=img_h,
downsample_width=img_w / (pool_size_1 * pool_size_2) - 2,
downsample_width=img_w // (pool_size_1 * pool_size_2) - 2,
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)
@@ -395,7 +423,7 @@ inner = Convolution2D(conv_num_filters, filter_size, filter_size, border_mode='s
activation=act, name='conv2')(inner)
inner = MaxPooling2D(pool_size=(pool_size_2, pool_size_2), name='max2')(inner)
conv_to_rnn_dims = ((img_h / (pool_size_1 * pool_size_2)) * conv_num_filters, img_w / (pool_size_1 * pool_size_2))
conv_to_rnn_dims = ((img_h // (pool_size_1 * pool_size_2)) * conv_num_filters, img_w // (pool_size_1 * pool_size_2))
inner = Reshape(target_shape=conv_to_rnn_dims, name='reshape')(inner)
inner = Permute(dims=(2, 1), name='permute')(inner)
+3 -7
Ver Arquivo
@@ -12,9 +12,9 @@ np.random.seed(1337) # for reproducibility
from keras.preprocessing import sequence
from keras.models import Sequential
from keras.layers import Dense, Dropout, Activation, Flatten
from keras.layers import Dense, Dropout, Activation
from keras.layers import Embedding
from keras.layers import Convolution1D, MaxPooling1D
from keras.layers import Convolution1D, GlobalMaxPooling1D
from keras.datasets import imdb
from keras import backend as K
@@ -58,11 +58,7 @@ model.add(Convolution1D(nb_filter=nb_filter,
activation='relu',
subsample_length=1))
# we use max pooling:
model.add(MaxPooling1D(pool_length=model.output_shape[1]))
# We flatten the output of the conv layer,
# so that we can add a vanilla dense layer:
model.add(Flatten())
model.add(GlobalMaxPooling1D())
# We add a vanilla hidden layer:
model.add(Dense(hidden_dims))
+1 -1
Ver Arquivo
@@ -11,7 +11,7 @@ from keras.preprocessing import sequence
from keras.models import Sequential
from keras.layers import Dense, Dropout, Activation
from keras.layers import Embedding
from keras.layers import LSTM, GRU, SimpleRNN
from keras.layers import LSTM
from keras.layers import Convolution1D, MaxPooling1D
from keras.datasets import imdb
+79 -11
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. 8s/epoch on i7 cpu.
Bi-gram : 0.9056 test accuracy after 5 epochs. 2s/epoch on GTX 980M gpu.
'''
from __future__ import print_function
@@ -15,23 +16,93 @@ np.random.seed(1337) # for reproducibility
from keras.preprocessing import sequence
from keras.models import Sequential
from keras.layers import Dense, Flatten
from keras.layers import Dense
from keras.layers import Embedding
from keras.layers import AveragePooling1D
from keras.layers import GlobalAveragePooling1D
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)
@@ -48,12 +119,9 @@ model.add(Embedding(max_features,
embedding_dims,
input_length=maxlen))
# we add a AveragePooling1D, which will average the embeddings
# we add a GlobalAveragePooling1D, which will average the embeddings
# of all words in the document
model.add(AveragePooling1D(pool_length=model.output_shape[1]))
# We flatten the output of the AveragePooling1D layer
model.add(Flatten())
model.add(GlobalAveragePooling1D())
# We project onto a single unit output layer, and squash it with a sigmoid:
model.add(Dense(1, activation='sigmoid'))
+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).
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@@ -0,0 +1,310 @@
#!/usr/bin/env python
# -*- coding: utf-8 -*-
"""
Train an Auxiliary Classifier Generative Adversarial Network (ACGAN) on the
MNIST dataset. See https://arxiv.org/abs/1610.09585 for more details.
You should start to see reasonable images after ~5 epochs, and good images
by ~15 epochs. You should use a GPU, as the convolution-heavy operations are
very slow on the CPU. Prefer the TensorFlow backend if you plan on iterating, as
the compilation time can be a blocker using Theano.
Timings:
Hardware | Backend | Time / Epoch
-------------------------------------------
CPU | TF | 3 hrs
Titan X (maxwell) | TF | 4 min
Titan X (maxwell) | TH | 7 min
Consult https://github.com/lukedeo/keras-acgan for more information and
example output
"""
from __future__ import print_function
from collections import defaultdict
try:
import cPickle as pickle
except ImportError:
import pickle
from PIL import Image
from six.moves import range
import keras.backend as K
from keras.datasets import mnist
from keras.layers import Input, Dense, Reshape, Flatten, Embedding, merge, Dropout
from keras.layers.advanced_activations import LeakyReLU
from keras.layers.convolutional import UpSampling2D, Convolution2D
from keras.models import Sequential, Model
from keras.optimizers import Adam
from keras.utils.generic_utils import Progbar
import numpy as np
np.random.seed(1337)
K.set_image_dim_ordering('th')
def build_generator(latent_size):
# we will map a pair of (z, L), where z is a latent vector and L is a
# label drawn from P_c, to image space (..., 1, 28, 28)
cnn = Sequential()
cnn.add(Dense(1024, input_dim=latent_size, activation='relu'))
cnn.add(Dense(128 * 7 * 7, activation='relu'))
cnn.add(Reshape((128, 7, 7)))
# upsample to (..., 14, 14)
cnn.add(UpSampling2D(size=(2, 2)))
cnn.add(Convolution2D(256, 5, 5, border_mode='same',
activation='relu', init='glorot_normal'))
# upsample to (..., 28, 28)
cnn.add(UpSampling2D(size=(2, 2)))
cnn.add(Convolution2D(128, 5, 5, border_mode='same',
activation='relu', init='glorot_normal'))
# take a channel axis reduction
cnn.add(Convolution2D(1, 2, 2, border_mode='same',
activation='tanh', init='glorot_normal'))
# this is the z space commonly refered to in GAN papers
latent = Input(shape=(latent_size, ))
# this will be our label
image_class = Input(shape=(1,), dtype='int32')
# 10 classes in MNIST
cls = Flatten()(Embedding(10, latent_size,
init='glorot_normal')(image_class))
# hadamard product between z-space and a class conditional embedding
h = merge([latent, cls], mode='mul')
fake_image = cnn(h)
return Model(input=[latent, image_class], output=fake_image)
def build_discriminator():
# build a relatively standard conv net, with LeakyReLUs as suggested in
# the reference paper
cnn = Sequential()
cnn.add(Convolution2D(32, 3, 3, border_mode='same', subsample=(2, 2),
input_shape=(1, 28, 28)))
cnn.add(LeakyReLU())
cnn.add(Dropout(0.3))
cnn.add(Convolution2D(64, 3, 3, border_mode='same', subsample=(1, 1)))
cnn.add(LeakyReLU())
cnn.add(Dropout(0.3))
cnn.add(Convolution2D(128, 3, 3, border_mode='same', subsample=(2, 2)))
cnn.add(LeakyReLU())
cnn.add(Dropout(0.3))
cnn.add(Convolution2D(256, 3, 3, border_mode='same', subsample=(1, 1)))
cnn.add(LeakyReLU())
cnn.add(Dropout(0.3))
cnn.add(Flatten())
image = Input(shape=(1, 28, 28))
features = cnn(image)
# first output (name=generation) is whether or not the discriminator
# thinks the image that is being shown is fake, and the second output
# (name=auxiliary) is the class that the discriminator thinks the image
# belongs to.
fake = Dense(1, activation='sigmoid', name='generation')(features)
aux = Dense(10, activation='softmax', name='auxiliary')(features)
return Model(input=image, output=[fake, aux])
if __name__ == '__main__':
# batch and latent size taken from the paper
nb_epochs = 50
batch_size = 100
latent_size = 100
# Adam parameters suggested in https://arxiv.org/abs/1511.06434
adam_lr = 0.0002
adam_beta_1 = 0.5
# build the discriminator
discriminator = build_discriminator()
discriminator.compile(
optimizer=Adam(lr=adam_lr, beta_1=adam_beta_1),
loss=['binary_crossentropy', 'sparse_categorical_crossentropy']
)
# build the generator
generator = build_generator(latent_size)
generator.compile(optimizer=Adam(lr=adam_lr, beta_1=adam_beta_1),
loss='binary_crossentropy')
latent = Input(shape=(latent_size, ))
image_class = Input(shape=(1,), dtype='int32')
# get a fake image
fake = generator([latent, image_class])
# we only want to be able to train generation for the combined model
discriminator.trainable = False
fake, aux = discriminator(fake)
combined = Model(input=[latent, image_class], output=[fake, aux])
combined.compile(
optimizer=Adam(lr=adam_lr, beta_1=adam_beta_1),
loss=['binary_crossentropy', 'sparse_categorical_crossentropy']
)
# get our mnist data, and force it to be of shape (..., 1, 28, 28) with
# range [-1, 1]
(X_train, y_train), (X_test, y_test) = mnist.load_data()
X_train = (X_train.astype(np.float32) - 127.5) / 127.5
X_train = np.expand_dims(X_train, axis=1)
X_test = (X_test.astype(np.float32) - 127.5) / 127.5
X_test = np.expand_dims(X_test, axis=1)
nb_train, nb_test = X_train.shape[0], X_test.shape[0]
train_history = defaultdict(list)
test_history = defaultdict(list)
for epoch in range(nb_epochs):
print('Epoch {} of {}'.format(epoch + 1, nb_epochs))
nb_batches = int(X_train.shape[0] / batch_size)
progress_bar = Progbar(target=nb_batches)
epoch_gen_loss = []
epoch_disc_loss = []
for index in range(nb_batches):
progress_bar.update(index)
# generate a new batch of noise
noise = np.random.uniform(-1, 1, (batch_size, latent_size))
# get a batch of real images
image_batch = X_train[index * batch_size:(index + 1) * batch_size]
label_batch = y_train[index * batch_size:(index + 1) * batch_size]
# sample some labels from p_c
sampled_labels = np.random.randint(0, 10, batch_size)
# generate a batch of fake images, using the generated labels as a
# conditioner. We reshape the sampled labels to be
# (batch_size, 1) so that we can feed them into the embedding
# layer as a length one sequence
generated_images = generator.predict(
[noise, sampled_labels.reshape((-1, 1))], verbose=0)
X = np.concatenate((image_batch, generated_images))
y = np.array([1] * batch_size + [0] * batch_size)
aux_y = np.concatenate((label_batch, sampled_labels), axis=0)
# see if the discriminator can figure itself out...
epoch_disc_loss.append(discriminator.train_on_batch(X, [y, aux_y]))
# make new noise. we generate 2 * batch size here such that we have
# the generator optimize over an identical number of images as the
# discriminator
noise = np.random.uniform(-1, 1, (2 * batch_size, latent_size))
sampled_labels = np.random.randint(0, 10, 2 * batch_size)
# we want to train the genrator to trick the discriminator
# For the generator, we want all the {fake, not-fake} labels to say
# not-fake
trick = np.ones(2 * batch_size)
epoch_gen_loss.append(combined.train_on_batch(
[noise, sampled_labels.reshape((-1, 1))], [trick, sampled_labels]))
print('\nTesting for epoch {}:'.format(epoch + 1))
# evaluate the testing loss here
# generate a new batch of noise
noise = np.random.uniform(-1, 1, (nb_test, latent_size))
# sample some labels from p_c and generate images from them
sampled_labels = np.random.randint(0, 10, nb_test)
generated_images = generator.predict(
[noise, sampled_labels.reshape((-1, 1))], verbose=False)
X = np.concatenate((X_test, generated_images))
y = np.array([1] * nb_test + [0] * nb_test)
aux_y = np.concatenate((y_test, sampled_labels), axis=0)
# see if the discriminator can figure itself out...
discriminator_test_loss = discriminator.evaluate(
X, [y, aux_y], verbose=False)
discriminator_train_loss = np.mean(np.array(epoch_disc_loss), axis=0)
# make new noise
noise = np.random.uniform(-1, 1, (2 * nb_test, latent_size))
sampled_labels = np.random.randint(0, 10, 2 * nb_test)
trick = np.ones(2 * nb_test)
generator_test_loss = combined.evaluate(
[noise, sampled_labels.reshape((-1, 1))],
[trick, sampled_labels], verbose=False)
generator_train_loss = np.mean(np.array(epoch_gen_loss), axis=0)
# generate an epoch report on performance
train_history['generator'].append(generator_train_loss)
train_history['discriminator'].append(discriminator_train_loss)
test_history['generator'].append(generator_test_loss)
test_history['discriminator'].append(discriminator_test_loss)
print('{0:<22s} | {1:4s} | {2:15s} | {3:5s}'.format(
'component', *discriminator.metrics_names))
print('-' * 65)
ROW_FMT = '{0:<22s} | {1:<4.2f} | {2:<15.2f} | {3:<5.2f}'
print(ROW_FMT.format('generator (train)',
*train_history['generator'][-1]))
print(ROW_FMT.format('generator (test)',
*test_history['generator'][-1]))
print(ROW_FMT.format('discriminator (train)',
*train_history['discriminator'][-1]))
print(ROW_FMT.format('discriminator (test)',
*test_history['discriminator'][-1]))
# save weights every epoch
generator.save_weights(
'params_generator_epoch_{0:03d}.hdf5'.format(epoch), True)
discriminator.save_weights(
'params_discriminator_epoch_{0:03d}.hdf5'.format(epoch), True)
# generate some digits to display
noise = np.random.uniform(-1, 1, (100, latent_size))
sampled_labels = np.array([
[i] * 10 for i in range(10)
]).reshape(-1, 1)
# get a batch to display
generated_images = generator.predict(
[noise, sampled_labels], verbose=0)
# arrange them into a grid
img = (np.concatenate([r.reshape(-1, 28)
for r in np.split(generated_images, 10)
], axis=-1) * 127.5 + 127.5).astype(np.uint8)
Image.fromarray(img).save(
'plot_epoch_{0:03d}_generated.png'.format(epoch))
pickle.dump({'train': train_history, 'test': test_history},
open('acgan-history.pkl', 'wb'))
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@@ -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())
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@@ -55,6 +55,7 @@ Results
'''
from __future__ import print_function
from six.moves import xrange
import numpy as np
np.random.seed(1337)
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@@ -75,7 +75,7 @@ def create_base_network(input_dim):
def compute_accuracy(predictions, labels):
'''Compute classification accuracy with a fixed threshold on distances.
'''
return labels[predictions.ravel() < 0.5].mean()
return np.mean(labels == (predictions.ravel() > 0.5))
# the data, shuffled and split between train and test sets
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@@ -0,0 +1,176 @@
'''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)
if K.backend() == 'tensorflow':
raise Exception('This example can only run with the '
'Theano backend for the time being, '
'because it requires taking the gradient '
'of a gradient, which isn\'t '
'supported for all TF ops.')
# This example assume 'th' dim ordering.
K.set_image_dim_ordering('th')
# 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,
+366
Ver Arquivo
@@ -0,0 +1,366 @@
'''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))
# Remove zero-center by mean pixel
x[:, :, 0] += 103.939
x[:, :, 1] += 116.779
x[:, :, 2] += 123.68
# 'BGR'->'RGB'
x = x[:, :, ::-1]
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))
+69 -94
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
@@ -13,9 +8,15 @@ e.g.:
```
python neural_style_transfer.py img/tuebingen.jpg img/starry_night.jpg results/my_result
```
Optional parameters:
```
--iter, To specify the number of iterations the style transfer takes place (Default is 10)
--content_weight, The weight given to the content loss (Default is 0.025)
--style_weight, The weight given to the style loss (Default is 1.0)
--tv_weight, The weight given to the total variation loss (Default is 1.0)
```
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 +50,14 @@ 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.')
@@ -68,41 +67,51 @@ parser.add_argument('style_reference_image_path', metavar='ref', type=str,
help='Path to the style reference image.')
parser.add_argument('result_prefix', metavar='res_prefix', type=str,
help='Prefix for the saved results.')
parser.add_argument('--iter', type=int, default=10, required=False,
help='Number of iterations to run.')
parser.add_argument('--content_weight', type=float, default=0.025, required=False,
help='Content weight.')
parser.add_argument('--style_weight', type=float, default=1.0, required=False,
help='Style weight.')
parser.add_argument('--tv_weight', type=float, default=1.0, required=False,
help='Total Variation weight.')
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'
iterations = args.iter
# these are the weights of the different loss components
total_variation_weight = 1.
style_weight = 1.
content_weight = 0.025
total_variation_weight = args.tv_weight
style_weight = args.style_weight
content_weight = args.content_weight
# 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))
# Remove zero-center by mean pixel
x[:, :, 0] += 103.939
x[:, :, 1] += 116.779
x[:, :, 2] += 123.68
# 'BGR'->'RGB'
x = x[:, :, ::-1]
x = np.clip(x, 0, 255).astype('uint8')
return x
@@ -112,7 +121,10 @@ 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 +132,9 @@ 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 +146,10 @@ 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 +164,7 @@ 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 +177,25 @@ 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 +214,12 @@ 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:
@@ -283,18 +257,19 @@ 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
for i in range(10):
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(iterations):
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().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
Ver Arquivo
@@ -54,7 +54,6 @@ model.add(LSTM(50,
return_sequences=True,
stateful=True))
model.add(LSTM(50,
batch_input_shape=(batch_size, tsteps, 1),
return_sequences=False,
stateful=True))
model.add(Dense(1))
+9 -5
Ver Arquivo
@@ -4,6 +4,7 @@ Reference: "Auto-Encoding Variational Bayes" https://arxiv.org/abs/1312.6114
'''
import numpy as np
import matplotlib.pyplot as plt
from scipy.stats import norm
from keras.layers import Input, Dense, Lambda
from keras.models import Model
@@ -16,6 +17,7 @@ original_dim = 784
latent_dim = 2
intermediate_dim = 256
nb_epoch = 50
epsilon_std = 1.0
x = Input(batch_shape=(batch_size, original_dim))
h = Dense(intermediate_dim, activation='relu')(x)
@@ -25,7 +27,8 @@ z_log_var = Dense(latent_dim)(h)
def sampling(args):
z_mean, z_log_var = args
epsilon = K.random_normal(shape=(batch_size, latent_dim), mean=0.)
epsilon = K.random_normal(shape=(batch_size, latent_dim), mean=0.,
std=epsilon_std)
return z_mean + K.exp(z_log_var / 2) * epsilon
# note that "output_shape" isn't necessary with the TensorFlow backend
@@ -80,9 +83,10 @@ generator = Model(decoder_input, _x_decoded_mean)
n = 15 # figure with 15x15 digits
digit_size = 28
figure = np.zeros((digit_size * n, digit_size * n))
# we will sample n points within [-15, 15] standard deviations
grid_x = np.linspace(-15, 15, n)
grid_y = np.linspace(-15, 15, n)
# linearly spaced coordinates on the unit square were transformed through the inverse CDF (ppf) of the Gaussian
# to produce values of the latent variables z, since the prior of the latent space is Gaussian
grid_x = norm.ppf(np.linspace(0.05, 0.95, n))
grid_y = norm.ppf(np.linspace(0.05, 0.95, n))
for i, yi in enumerate(grid_x):
for j, xi in enumerate(grid_y):
@@ -93,5 +97,5 @@ for i, yi in enumerate(grid_x):
j * digit_size: (j + 1) * digit_size] = digit
plt.figure(figsize=(10, 10))
plt.imshow(figure)
plt.imshow(figure, cmap='Greys_r')
plt.show()
+89 -40
Ver Arquivo
@@ -1,12 +1,14 @@
'''This script demonstrates how to build a variational autoencoder with Keras and deconvolution layers.
'''This script demonstrates how to build a variational autoencoder
with Keras and deconvolution layers.
Reference: "Auto-Encoding Variational Bayes" https://arxiv.org/abs/1312.6114
'''
import numpy as np
import matplotlib.pyplot as plt
from scipy.stats import norm
from keras.layers import Input, Dense, Lambda, Flatten, Reshape
from keras.layers import Convolution2D, Deconvolution2D, MaxPooling2D
from keras.layers import Convolution2D, Deconvolution2D
from keras.models import Model
from keras import backend as K
from keras import objectives
@@ -15,25 +17,36 @@ from keras.datasets import mnist
# input image dimensions
img_rows, img_cols, img_chns = 28, 28, 1
# number of convolutional filters to use
nb_filters = 32
nb_filters = 64
# convolution kernel size
nb_conv = 3
batch_size = 16
original_dim = (img_chns, img_rows, img_cols)
batch_size = 100
if K.image_dim_ordering() == 'th':
original_img_size = (img_chns, img_rows, img_cols)
else:
original_img_size = (img_rows, img_cols, img_chns)
latent_dim = 2
intermediate_dim = 128
epsilon_std = 0.01
epsilon_std = 1.0
nb_epoch = 5
x = Input(batch_shape=(batch_size,) + original_img_size)
conv_1 = Convolution2D(img_chns, 2, 2, border_mode='same', activation='relu')(x)
conv_2 = Convolution2D(nb_filters, 2, 2,
border_mode='same', activation='relu',
subsample=(2, 2))(conv_1)
conv_3 = Convolution2D(nb_filters, nb_conv, nb_conv,
border_mode='same', activation='relu',
subsample=(1, 1))(conv_2)
conv_4 = Convolution2D(nb_filters, nb_conv, nb_conv,
border_mode='same', activation='relu',
subsample=(1, 1))(conv_3)
flat = Flatten()(conv_4)
hidden = Dense(intermediate_dim, activation='relu')(flat)
x = Input(batch_shape=(batch_size,) + original_dim)
c = Convolution2D(nb_filters, nb_conv, nb_conv, border_mode='same', activation='relu')(x)
f = Flatten()(c)
h = Dense(intermediate_dim, activation='relu')(f)
z_mean = Dense(latent_dim)(h)
z_log_var = Dense(latent_dim)(h)
z_mean = Dense(latent_dim)(hidden)
z_log_var = Dense(latent_dim)(hidden)
def sampling(args):
@@ -47,36 +60,68 @@ def sampling(args):
z = Lambda(sampling, output_shape=(latent_dim,))([z_mean, z_log_var])
# we instantiate these layers separately so as to reuse them later
decoder_h = Dense(intermediate_dim, activation='relu')
decoder_f = Dense(nb_filters*img_rows*img_cols, activation='relu')
decoder_c = Reshape((nb_filters, img_rows, img_cols))
decoder_mean = Deconvolution2D(img_chns, nb_conv, nb_conv,
(batch_size, img_chns, img_rows, img_cols),
border_mode='same')
decoder_hid = Dense(intermediate_dim, activation='relu')
decoder_upsample = Dense(nb_filters * 14 * 14, activation='relu')
h_decoded = decoder_h(z)
f_decoded = decoder_f(h_decoded)
c_decoded = decoder_c(f_decoded)
x_decoded_mean = decoder_mean(c_decoded)
if K.image_dim_ordering() == 'th':
output_shape = (batch_size, nb_filters, 14, 14)
else:
output_shape = (batch_size, 14, 14, nb_filters)
decoder_reshape = Reshape(output_shape[1:])
decoder_deconv_1 = Deconvolution2D(nb_filters, nb_conv, nb_conv,
output_shape,
border_mode='same',
subsample=(1, 1),
activation='relu')
decoder_deconv_2 = Deconvolution2D(nb_filters, nb_conv, nb_conv,
output_shape,
border_mode='same',
subsample=(1, 1),
activation='relu')
if K.image_dim_ordering() == 'th':
output_shape = (batch_size, nb_filters, 29, 29)
else:
output_shape = (batch_size, 29, 29, nb_filters)
decoder_deconv_3_upsamp = Deconvolution2D(nb_filters, 2, 2,
output_shape,
border_mode='valid',
subsample=(2, 2),
activation='relu')
decoder_mean_squash = Convolution2D(img_chns, 2, 2,
border_mode='valid',
activation='sigmoid')
hid_decoded = decoder_hid(z)
up_decoded = decoder_upsample(hid_decoded)
reshape_decoded = decoder_reshape(up_decoded)
deconv_1_decoded = decoder_deconv_1(reshape_decoded)
deconv_2_decoded = decoder_deconv_2(deconv_1_decoded)
x_decoded_relu = decoder_deconv_3_upsamp(deconv_2_decoded)
x_decoded_mean_squash = decoder_mean_squash(x_decoded_relu)
def vae_loss(x, x_decoded_mean):
# NOTE: binary_crossentropy expects a batch_size by dim for x and x_decoded_mean, so we MUST flatten these!
# NOTE: binary_crossentropy expects a batch_size by dim
# for x and x_decoded_mean, so we MUST flatten these!
x = K.flatten(x)
x_decoded_mean = K.flatten(x_decoded_mean)
xent_loss = objectives.binary_crossentropy(x, x_decoded_mean)
xent_loss = img_rows * img_cols * objectives.binary_crossentropy(x, x_decoded_mean)
kl_loss = - 0.5 * K.mean(1 + z_log_var - K.square(z_mean) - K.exp(z_log_var), axis=-1)
return xent_loss + kl_loss
vae = Model(x, x_decoded_mean)
vae = Model(x, x_decoded_mean_squash)
vae.compile(optimizer='rmsprop', loss=vae_loss)
vae.summary()
# train the VAE on MNIST digits
(x_train, y_train), (x_test, y_test) = mnist.load_data()
(x_train, _), (x_test, y_test) = mnist.load_data()
x_train = x_train.astype('float32')[:, None, :, :] / 255.
x_test = x_test.astype('float32')[:, None, :, :] / 255.
x_train = x_train.astype('float32') / 255.
x_train = x_train.reshape((x_train.shape[0],) + original_img_size)
x_test = x_test.astype('float32') / 255.
x_test = x_test.reshape((x_test.shape[0],) + original_img_size)
print('x_train.shape:', x_train.shape)
vae.fit(x_train, x_train,
shuffle=True,
@@ -84,7 +129,6 @@ vae.fit(x_train, x_train,
batch_size=batch_size,
validation_data=(x_test, x_test))
# build a model to project inputs on the latent space
encoder = Model(x, z_mean)
@@ -97,28 +141,33 @@ plt.show()
# build a digit generator that can sample from the learned distribution
decoder_input = Input(shape=(latent_dim,))
_h_decoded = decoder_h(decoder_input)
_f_decoded = decoder_f(_h_decoded)
_c_decoded = decoder_c(_f_decoded)
_x_decoded_mean = decoder_mean(_c_decoded)
generator = Model(decoder_input, _x_decoded_mean)
_hid_decoded = decoder_hid(decoder_input)
_up_decoded = decoder_upsample(_hid_decoded)
_reshape_decoded = decoder_reshape(_up_decoded)
_deconv_1_decoded = decoder_deconv_1(_reshape_decoded)
_deconv_2_decoded = decoder_deconv_2(_deconv_1_decoded)
_x_decoded_relu = decoder_deconv_3_upsamp(_deconv_2_decoded)
_x_decoded_mean_squash = decoder_mean_squash(_x_decoded_relu)
generator = Model(decoder_input, _x_decoded_mean_squash)
# display a 2D manifold of the digits
n = 15 # figure with 15x15 digits
digit_size = 28
figure = np.zeros((digit_size * n, digit_size * n))
# we will sample n points within [-15, 15] standard deviations
grid_x = np.linspace(-15, 15, n)
grid_y = np.linspace(-15, 15, n)
# linearly spaced coordinates on the unit square were transformed through the inverse CDF (ppf) of the Gaussian
# to produce values of the latent variables z, since the prior of the latent space is Gaussian
grid_x = norm.ppf(np.linspace(0.05, 0.95, n))
grid_y = norm.ppf(np.linspace(0.05, 0.95, n))
for i, yi in enumerate(grid_x):
for j, xi in enumerate(grid_y):
z_sample = np.array([[xi, yi]])
x_decoded = generator.predict(z_sample)
z_sample = np.tile(z_sample, batch_size).reshape(batch_size, 2)
x_decoded = generator.predict(z_sample, batch_size=batch_size)
digit = x_decoded[0].reshape(digit_size, digit_size)
figure[i * digit_size: (i + 1) * digit_size,
j * digit_size: (j + 1) * digit_size] = digit
plt.figure(figsize=(10, 10))
plt.imshow(figure)
plt.imshow(figure, cmap='Greys_r')
plt.show()
+1 -1
Ver Arquivo
@@ -15,4 +15,4 @@ from . import objectives
from . import optimizers
from . import regularizers
__version__ = '1.0.8'
__version__ = '1.2.0'
+8 -6
Ver Arquivo
@@ -1,5 +1,6 @@
from __future__ import absolute_import
from . import backend as K
from .utils.generic_utils import get_from_module
def softmax(x):
@@ -11,8 +12,13 @@ def softmax(x):
s = K.sum(e, axis=-1, keepdims=True)
return e / s
else:
raise Exception('Cannot apply softmax to a tensor that is not 2D or 3D. ' +
'Here, ndim=' + str(ndim))
raise ValueError('Cannot apply softmax to a tensor '
'that is not 2D or 3D. '
'Here, ndim=' + str(ndim))
def elu(x, alpha=1.0):
return K.elu(x, alpha)
def softplus(x):
@@ -40,13 +46,9 @@ def hard_sigmoid(x):
def linear(x):
'''
The function returns the variable that is passed in, so all types work.
'''
return x
from .utils.generic_utils import get_from_module
def get(identifier):
if identifier is None:
return linear
+5
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@@ -0,0 +1,5 @@
from .vgg16 import VGG16
from .vgg19 import VGG19
from .resnet50 import ResNet50
from .inception_v3 import InceptionV3
from .xception import Xception
+86
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@@ -0,0 +1,86 @@
import numpy as np
from .. import backend as K
TAGS = ['rock', 'pop', 'alternative', 'indie', 'electronic',
'female vocalists', 'dance', '00s', 'alternative rock', 'jazz',
'beautiful', 'metal', 'chillout', 'male vocalists',
'classic rock', 'soul', 'indie rock', 'Mellow', 'electronica',
'80s', 'folk', '90s', 'chill', 'instrumental', 'punk',
'oldies', 'blues', 'hard rock', 'ambient', 'acoustic',
'experimental', 'female vocalist', 'guitar', 'Hip-Hop',
'70s', 'party', 'country', 'easy listening',
'sexy', 'catchy', 'funk', 'electro', 'heavy metal',
'Progressive rock', '60s', 'rnb', 'indie pop',
'sad', 'House', 'happy']
def librosa_exists():
try:
__import__('librosa')
except ImportError:
return False
else:
return True
def preprocess_input(audio_path, dim_ordering='default'):
'''Reads an audio file and outputs a Mel-spectrogram.
'''
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
assert dim_ordering in {'tf', 'th'}
if librosa_exists():
import librosa
else:
raise RuntimeError('Librosa is required to process audio files.\n' +
'Install it via `pip install librosa` \nor visit ' +
'http://librosa.github.io/librosa/ for details.')
# mel-spectrogram parameters
SR = 12000
N_FFT = 512
N_MELS = 96
HOP_LEN = 256
DURA = 29.12
src, sr = librosa.load(audio_path, sr=SR)
n_sample = src.shape[0]
n_sample_wanted = int(DURA * SR)
# trim the signal at the center
if n_sample < n_sample_wanted: # if too short
src = np.hstack((src, np.zeros((int(DURA * SR) - n_sample,))))
elif n_sample > n_sample_wanted: # if too long
src = src[(n_sample - n_sample_wanted) / 2:
(n_sample + n_sample_wanted) / 2]
logam = librosa.logamplitude
melgram = librosa.feature.melspectrogram
x = logam(melgram(y=src, sr=SR, hop_length=HOP_LEN,
n_fft=N_FFT, n_mels=N_MELS) ** 2,
ref_power=1.0)
if dim_ordering == 'th':
x = np.expand_dims(x, axis=0)
elif dim_ordering == 'tf':
x = np.expand_dims(x, axis=3)
return x
def decode_predictions(preds, top_n=5):
'''Decode the output of a music tagger model.
# Arguments
preds: 2-dimensional numpy array
top_n: integer in [0, 50], number of items to show
'''
assert len(preds.shape) == 2 and preds.shape[1] == 50
results = []
for pred in preds:
result = zip(TAGS, pred)
result = sorted(result, key=lambda x: x[1], reverse=True)
results.append(result[:top_n])
return results
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@@ -0,0 +1,94 @@
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':
# 'RGB'->'BGR'
x = x[:, ::-1, :, :]
# Zero-center by mean pixel
x[:, 0, :, :] -= 103.939
x[:, 1, :, :] -= 116.779
x[:, 2, :, :] -= 123.68
else:
# 'RGB'->'BGR'
x = x[:, :, :, ::-1]
# Zero-center by mean pixel
x[:, :, :, 0] -= 103.939
x[:, :, :, 1] -= 116.779
x[:, :, :, 2] -= 123.68
return x
def decode_predictions(preds, top=5):
global CLASS_INDEX
if len(preds.shape) != 2 or preds.shape[1] != 1000:
raise ValueError('`decode_predictions` expects '
'a batch of predictions '
'(i.e. a 2D array of shape (samples, 1000)). '
'Found array with shape: ' + str(preds.shape))
if CLASS_INDEX is None:
fpath = get_file('imagenet_class_index.json',
CLASS_INDEX_PATH,
cache_subdir='models')
CLASS_INDEX = json.load(open(fpath))
results = []
for pred in preds:
top_indices = pred.argsort()[-top:][::-1]
result = [tuple(CLASS_INDEX[str(i)]) + (pred[i],) for i in top_indices]
result.sort(key=lambda x: x[2], reverse=True)
results.append(result)
return results
def _obtain_input_shape(input_shape, default_size, min_size, dim_ordering, include_top):
if dim_ordering == 'th':
default_shape = (3, default_size, default_size)
else:
default_shape = (default_size, default_size, 3)
if include_top:
if input_shape is not None:
if input_shape != default_shape:
raise ValueError('When setting`include_top=True`, '
'`input_shape` should be ' + str(default_shape) + '.')
input_shape = default_shape
else:
if dim_ordering == 'th':
if input_shape is not None:
if len(input_shape) != 3:
raise ValueError('`input_shape` must be a tuple of three integers.')
if input_shape[0] != 3:
raise ValueError('The input must have 3 channels; got '
'`input_shape=' + str(input_shape) + '`')
if ((input_shape[1] is not None and input_shape[1] < min_size) or
(input_shape[2] is not None and input_shape[2] < min_size)):
raise ValueError('Input size must be at least ' +
str(min_size) + 'x' + str(min_size) + ', got '
'`input_shape=' + str(input_shape) + '`')
else:
input_shape = (3, None, None)
else:
if input_shape is not None:
if len(input_shape) != 3:
raise ValueError('`input_shape` must be a tuple of three integers.')
if input_shape[-1] != 3:
raise ValueError('The input must have 3 channels; got '
'`input_shape=' + str(input_shape) + '`')
if ((input_shape[0] is not None and input_shape[0] < min_size) or
(input_shape[1] is not None and input_shape[1] < min_size)):
raise ValueError('Input size must be at least ' +
str(min_size) + 'x' + str(min_size) + ', got '
'`input_shape=' + str(input_shape) + '`')
else:
input_shape = (None, None, 3)
return input_shape
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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
the VGG16 and ResNet models (299x299 instead of 224x224), and that the input preprocessing function
is also different (same as Xception).
# 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 ..engine.topology import get_source_inputs
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, _obtain_input_shape
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, input_shape=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 fully-connected
layer 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.
inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(299, 299, 3)` (with `tf` dim ordering)
or `(3, 299, 299)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 139.
E.g. `(150, 150, 3)` would be one valid value.
# 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
input_shape = _obtain_input_shape(input_shape,
default_size=299,
min_size=139,
dim_ordering=K.image_dim_ordering(),
include_top=include_top)
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)
# Ensure that the model takes into account
# any potential predecessors of `input_tensor`.
if input_tensor is not None:
inputs = get_source_inputs(input_tensor)
else:
inputs = img_input
# Create model.
model = Model(inputs, x, name='inception_v3')
# 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 -*-
'''MusicTaggerCRNN model for Keras.
# Reference:
- [Music-auto_tagging-keras](https://github.com/keunwoochoi/music-auto_tagging-keras)
'''
from __future__ import print_function
from __future__ import absolute_import
from .. import backend as K
from ..layers import Input, Dense
from ..models import Model
from ..layers import Dense, Dropout, Reshape, Permute
from ..layers.convolutional import Convolution2D
from ..layers.convolutional import MaxPooling2D, ZeroPadding2D
from ..layers.normalization import BatchNormalization
from ..layers.advanced_activations import ELU
from ..layers.recurrent import GRU
from ..engine.topology import get_source_inputs
from ..utils.data_utils import get_file
from ..utils.layer_utils import convert_all_kernels_in_model
from .audio_conv_utils import decode_predictions, preprocess_input
TH_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.3/music_tagger_crnn_weights_tf_kernels_th_dim_ordering.h5'
TF_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.3/music_tagger_crnn_weights_tf_kernels_tf_dim_ordering.h5'
def MusicTaggerCRNN(weights='msd', input_tensor=None,
include_top=True):
'''Instantiate the MusicTaggerCRNN architecture,
optionally loading weights pre-trained
on Million Song Dataset. 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.
For preparing mel-spectrogram input, see
`audio_conv_utils.py` in [applications](https://github.com/fchollet/keras/tree/master/keras/applications).
You will need to install [Librosa](http://librosa.github.io/librosa/)
to use it.
# Arguments
weights: one of `None` (random initialization)
or "msd" (pre-training on ImageNet).
input_tensor: optional Keras tensor (i.e. output of `layers.Input()`)
to use as image input for the model.
include_top: whether to include the 1 fully-connected
layer (output layer) at the top of the network.
If False, the network outputs 32-dim features.
# Returns
A Keras model instance.
'''
if weights not in {'msd', None}:
raise ValueError('The `weights` argument should be either '
'`None` (random initialization) or `msd` '
'(pre-training on Million Song Dataset).')
# Determine proper input shape
if K.image_dim_ordering() == 'th':
input_shape = (1, 96, 1366)
else:
input_shape = (96, 1366, 1)
if input_tensor is None:
melgram_input = Input(shape=input_shape)
else:
if not K.is_keras_tensor(input_tensor):
melgram_input = Input(tensor=input_tensor, shape=input_shape)
else:
melgram_input = input_tensor
# Determine input axis
if K.image_dim_ordering() == 'th':
channel_axis = 1
freq_axis = 2
time_axis = 3
else:
channel_axis = 3
freq_axis = 1
time_axis = 2
# Input block
x = ZeroPadding2D(padding=(0, 37))(melgram_input)
x = BatchNormalization(axis=time_axis, name='bn_0_freq')(x)
# Conv block 1
x = Convolution2D(64, 3, 3, border_mode='same', name='conv1')(x)
x = BatchNormalization(axis=channel_axis, mode=0, name='bn1')(x)
x = ELU()(x)
x = MaxPooling2D(pool_size=(2, 2), strides=(2, 2), name='pool1')(x)
# Conv block 2
x = Convolution2D(128, 3, 3, border_mode='same', name='conv2')(x)
x = BatchNormalization(axis=channel_axis, mode=0, name='bn2')(x)
x = ELU()(x)
x = MaxPooling2D(pool_size=(3, 3), strides=(3, 3), name='pool2')(x)
# Conv block 3
x = Convolution2D(128, 3, 3, border_mode='same', name='conv3')(x)
x = BatchNormalization(axis=channel_axis, mode=0, name='bn3')(x)
x = ELU()(x)
x = MaxPooling2D(pool_size=(4, 4), strides=(4, 4), name='pool3')(x)
# Conv block 4
x = Convolution2D(128, 3, 3, border_mode='same', name='conv4')(x)
x = BatchNormalization(axis=channel_axis, mode=0, name='bn4')(x)
x = ELU()(x)
x = MaxPooling2D(pool_size=(4, 4), strides=(4, 4), name='pool4')(x)
# reshaping
if K.image_dim_ordering() == 'th':
x = Permute((3, 1, 2))(x)
x = Reshape((15, 128))(x)
# GRU block 1, 2, output
x = GRU(32, return_sequences=True, name='gru1')(x)
x = GRU(32, return_sequences=False, name='gru2')(x)
if include_top:
x = Dense(50, activation='sigmoid', name='output')(x)
# Ensure that the model takes into account
# any potential predecessors of `input_tensor`.
if input_tensor is not None:
inputs = get_source_inputs(input_tensor)
else:
inputs = melgram_input
# Create model.
model = Model(inputs, x, name='music_tagger_crnn')
if weights is None:
return model
else:
# Load weights
if K.image_dim_ordering() == 'tf':
weights_path = get_file('music_tagger_crnn_weights_tf_kernels_tf_dim_ordering.h5',
TF_WEIGHTS_PATH,
cache_subdir='models')
else:
weights_path = get_file('music_tagger_crnn_weights_tf_kernels_th_dim_ordering.h5',
TH_WEIGHTS_PATH,
cache_subdir='models')
model.load_weights(weights_path, by_name=True)
if K.backend() == 'theano':
convert_all_kernels_in_model(model)
return model
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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 ..engine.topology import get_source_inputs
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, _obtain_input_shape
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, input_shape=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. output of `layers.Input()`)
to use as image input for the model.
inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(224, 224, 3)` (with `tf` dim ordering)
or `(3, 224, 244)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 197.
E.g. `(200, 200, 3)` would be one valid value.
# 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
input_shape = _obtain_input_shape(input_shape,
default_size=224,
min_size=197,
dim_ordering=K.image_dim_ordering(),
include_top=include_top)
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)
# Ensure that the model takes into account
# any potential predecessors of `input_tensor`.
if input_tensor is not None:
inputs = get_source_inputs(input_tensor)
else:
inputs = img_input
# Create model.
model = Model(inputs, x, name='resnet50')
# 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 ..engine.topology import get_source_inputs
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, _obtain_input_shape
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, input_shape=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.
inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(224, 224, 3)` (with `tf` dim ordering)
or `(3, 224, 244)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 48.
E.g. `(200, 200, 3)` would be one valid value.
# 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
input_shape = _obtain_input_shape(input_shape,
default_size=224,
min_size=48,
dim_ordering=K.image_dim_ordering(),
include_top=include_top)
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)
# Ensure that the model takes into account
# any potential predecessors of `input_tensor`.
if input_tensor is not None:
inputs = get_source_inputs(input_tensor)
else:
inputs = img_input
# Create model.
model = Model(inputs, x, name='vgg16')
# 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
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# -*- 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 ..engine.topology import get_source_inputs
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, _obtain_input_shape
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, input_shape=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.
inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(224, 224, 3)` (with `tf` dim ordering)
or `(3, 224, 244)` (with `th` dim ordering).
It should have exactly 3 inputs channels,
and width and height should be no smaller than 48.
E.g. `(200, 200, 3)` would be one valid value.
# 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
input_shape = _obtain_input_shape(input_shape,
default_size=224,
min_size=48,
dim_ordering=K.image_dim_ordering(),
include_top=include_top)
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)
# Ensure that the model takes into account
# any potential predecessors of `input_tensor`.
if input_tensor is not None:
inputs = get_source_inputs(input_tensor)
else:
inputs = img_input
# Create model.
model = Model(inputs, x, name='vgg19')
# 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
+224
Ver Arquivo
@@ -0,0 +1,224 @@
# -*- coding: utf-8 -*-
'''Xception V1 model for Keras.
On ImageNet, this model gets to a top-1 validation accuracy of 0.790
and a top-5 validation accuracy of 0.945.
Do note that the input image format for this model is different than for
the VGG16 and ResNet models (299x299 instead of 224x224),
and that the input preprocessing function
is also different (same as Inception V3).
Also do note that this model is only available for the TensorFlow backend,
due to its reliance on `SeparableConvolution` layers.
# Reference:
- [Xception: Deep Learning with Depthwise Separable Convolutions](https://arxiv.org/abs/1610.02357)
'''
from __future__ import print_function
from __future__ import absolute_import
import warnings
from ..models import Model
from ..layers import Dense, Input, BatchNormalization, Activation, merge
from ..layers import Conv2D, SeparableConv2D, MaxPooling2D, GlobalAveragePooling2D
from ..engine.topology import get_source_inputs
from ..utils.data_utils import get_file
from .. import backend as K
from .imagenet_utils import decode_predictions, _obtain_input_shape
TF_WEIGHTS_PATH = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.4/xception_weights_tf_dim_ordering_tf_kernels.h5'
TF_WEIGHTS_PATH_NO_TOP = 'https://github.com/fchollet/deep-learning-models/releases/download/v0.4/xception_weights_tf_dim_ordering_tf_kernels_notop.h5'
def Xception(include_top=True, weights='imagenet',
input_tensor=None, input_shape=None):
'''Instantiate the Xception architecture,
optionally loading weights pre-trained
on ImageNet. This model is available for TensorFlow only,
and can only be used with inputs following the TensorFlow
dimension ordering `(width, height, channels)`.
You should set `image_dim_ordering="tf"` in your Keras config
located at ~/.keras/keras.json.
Note that the default input image size for this model is 299x299.
# Arguments
include_top: whether to include the fully-connected
layer 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.
inputs_shape: optional shape tuple, only to be specified
if `include_top` is False (otherwise the input shape
has to be `(299, 299, 3)`.
It should have exactly 3 inputs channels,
and width and height should be no smaller than 71.
E.g. `(150, 150, 3)` would be one valid value.
# 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).')
if K.backend() != 'tensorflow':
raise RuntimeError('The Xception model is only available with '
'the TensorFlow backend.')
if K.image_dim_ordering() != 'tf':
warnings.warn('The Xception model is only available for the '
'input dimension ordering "tf" '
'(width, height, channels). '
'However your settings specify the default '
'dimension ordering "th" (channels, width, height). '
'You should set `image_dim_ordering="tf"` in your Keras '
'config located at ~/.keras/keras.json. '
'The model being returned right now will expect inputs '
'to follow the "tf" dimension ordering.')
K.set_image_dim_ordering('tf')
old_dim_ordering = 'th'
else:
old_dim_ordering = None
# Determine proper input shape
input_shape = _obtain_input_shape(input_shape,
default_size=299,
min_size=71,
dim_ordering=K.image_dim_ordering(),
include_top=include_top)
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
x = Conv2D(32, 3, 3, subsample=(2, 2), bias=False, name='block1_conv1')(img_input)
x = BatchNormalization(name='block1_conv1_bn')(x)
x = Activation('relu', name='block1_conv1_act')(x)
x = Conv2D(64, 3, 3, bias=False, name='block1_conv2')(x)
x = BatchNormalization(name='block1_conv2_bn')(x)
x = Activation('relu', name='block1_conv2_act')(x)
residual = Conv2D(128, 1, 1, subsample=(2, 2),
border_mode='same', bias=False)(x)
residual = BatchNormalization()(residual)
x = SeparableConv2D(128, 3, 3, border_mode='same', bias=False, name='block2_sepconv1')(x)
x = BatchNormalization(name='block2_sepconv1_bn')(x)
x = Activation('relu', name='block2_sepconv2_act')(x)
x = SeparableConv2D(128, 3, 3, border_mode='same', bias=False, name='block2_sepconv2')(x)
x = BatchNormalization(name='block2_sepconv2_bn')(x)
x = MaxPooling2D((3, 3), strides=(2, 2), border_mode='same', name='block2_pool')(x)
x = merge([x, residual], mode='sum')
residual = Conv2D(256, 1, 1, subsample=(2, 2),
border_mode='same', bias=False)(x)
residual = BatchNormalization()(residual)
x = Activation('relu', name='block3_sepconv1_act')(x)
x = SeparableConv2D(256, 3, 3, border_mode='same', bias=False, name='block3_sepconv1')(x)
x = BatchNormalization(name='block3_sepconv1_bn')(x)
x = Activation('relu', name='block3_sepconv2_act')(x)
x = SeparableConv2D(256, 3, 3, border_mode='same', bias=False, name='block3_sepconv2')(x)
x = BatchNormalization(name='block3_sepconv2_bn')(x)
x = MaxPooling2D((3, 3), strides=(2, 2), border_mode='same', name='block3_pool')(x)
x = merge([x, residual], mode='sum')
residual = Conv2D(728, 1, 1, subsample=(2, 2),
border_mode='same', bias=False)(x)
residual = BatchNormalization()(residual)
x = Activation('relu', name='block4_sepconv1_act')(x)
x = SeparableConv2D(728, 3, 3, border_mode='same', bias=False, name='block4_sepconv1')(x)
x = BatchNormalization(name='block4_sepconv1_bn')(x)
x = Activation('relu', name='block4_sepconv2_act')(x)
x = SeparableConv2D(728, 3, 3, border_mode='same', bias=False, name='block4_sepconv2')(x)
x = BatchNormalization(name='block4_sepconv2_bn')(x)
x = MaxPooling2D((3, 3), strides=(2, 2), border_mode='same', name='block4_pool')(x)
x = merge([x, residual], mode='sum')
for i in range(8):
residual = x
prefix = 'block' + str(i + 5)
x = Activation('relu', name=prefix + '_sepconv1_act')(x)
x = SeparableConv2D(728, 3, 3, border_mode='same', bias=False, name=prefix + '_sepconv1')(x)
x = BatchNormalization(name=prefix + '_sepconv1_bn')(x)
x = Activation('relu', name=prefix + '_sepconv2_act')(x)
x = SeparableConv2D(728, 3, 3, border_mode='same', bias=False, name=prefix + '_sepconv2')(x)
x = BatchNormalization(name=prefix + '_sepconv2_bn')(x)
x = Activation('relu', name=prefix + '_sepconv3_act')(x)
x = SeparableConv2D(728, 3, 3, border_mode='same', bias=False, name=prefix + '_sepconv3')(x)
x = BatchNormalization(name=prefix + '_sepconv3_bn')(x)
x = merge([x, residual], mode='sum')
residual = Conv2D(1024, 1, 1, subsample=(2, 2),
border_mode='same', bias=False)(x)
residual = BatchNormalization()(residual)
x = Activation('relu', name='block13_sepconv1_act')(x)
x = SeparableConv2D(728, 3, 3, border_mode='same', bias=False, name='block13_sepconv1')(x)
x = BatchNormalization(name='block13_sepconv1_bn')(x)
x = Activation('relu', name='block13_sepconv2_act')(x)
x = SeparableConv2D(1024, 3, 3, border_mode='same', bias=False, name='block13_sepconv2')(x)
x = BatchNormalization(name='block13_sepconv2_bn')(x)
x = MaxPooling2D((3, 3), strides=(2, 2), border_mode='same', name='block13_pool')(x)
x = merge([x, residual], mode='sum')
x = SeparableConv2D(1536, 3, 3, border_mode='same', bias=False, name='block14_sepconv1')(x)
x = BatchNormalization(name='block14_sepconv1_bn')(x)
x = Activation('relu', name='block14_sepconv1_act')(x)
x = SeparableConv2D(2048, 3, 3, border_mode='same', bias=False, name='block14_sepconv2')(x)
x = BatchNormalization(name='block14_sepconv2_bn')(x)
x = Activation('relu', name='block14_sepconv2_act')(x)
if include_top:
x = GlobalAveragePooling2D(name='avg_pool')(x)
x = Dense(1000, activation='softmax', name='predictions')(x)
# Ensure that the model takes into account
# any potential predecessors of `input_tensor`.
if input_tensor is not None:
inputs = get_source_inputs(input_tensor)
else:
inputs = img_input
# Create model.
model = Model(inputs, x, name='xception')
# load weights
if weights == 'imagenet':
if include_top:
weights_path = get_file('xception_weights_tf_dim_ordering_tf_kernels.h5',
TF_WEIGHTS_PATH,
cache_subdir='models')
else:
weights_path = get_file('xception_weights_tf_dim_ordering_tf_kernels_notop.h5',
TF_WEIGHTS_PATH_NO_TOP,
cache_subdir='models')
model.load_weights(weights_path)
if old_dim_ordering:
K.set_image_dim_ordering(old_dim_ordering)
return model
def preprocess_input(x):
x /= 255.
x -= 0.5
x *= 2.
return x
+7 -4
Ver Arquivo
@@ -23,17 +23,20 @@ _keras_dir = os.path.join(_keras_base_dir, '.keras')
if not os.path.exists(_keras_dir):
os.makedirs(_keras_dir)
_BACKEND = 'theano'
# Default backend: TensorFlow.
_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))
_floatx = _config.get('floatx', floatx())
assert _floatx in {'float16', 'float32', 'float64'}
_epsilon = _config.get('epsilon', epsilon())
assert type(_epsilon) == float
assert isinstance(_epsilon, float)
_backend = _config.get('backend', _BACKEND)
assert _backend in {'theano', 'tensorflow'}
_image_dim_ordering = _config.get('image_dim_ordering', image_dim_ordering())
_image_dim_ordering = _config.get('image_dim_ordering',
image_dim_ordering())
assert _image_dim_ordering in {'tf', 'th'}
set_floatx(_floatx)
@@ -63,7 +66,7 @@ elif _BACKEND == 'tensorflow':
sys.stderr.write('Using TensorFlow backend.\n')
from .tensorflow_backend import *
else:
raise Exception('Unknown backend: ' + str(_BACKEND))
raise ValueError('Unknown backend: ' + str(_BACKEND))
def backend():
+133 -5
Ver Arquivo
@@ -6,13 +6,22 @@ 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
def epsilon():
'''Returns the value of the fuzz
factor used in numeric expressions.
# Returns
A float.
# Example
```python
>>> keras.backend.epsilon()
1e-08
```
'''
return _EPSILON
@@ -20,6 +29,19 @@ def epsilon():
def set_epsilon(e):
'''Sets the value of the fuzz
factor used in numeric expressions.
# Arguments
e: float. New value of epsilon.
# Example
```python
>>> from keras import backend as K
>>> K.epsilon()
1e-08
>>> K.set_epsilon(1e-05)
>>> K.epsilon()
1e-05
```
'''
global _EPSILON
_EPSILON = e
@@ -28,26 +50,80 @@ def set_epsilon(e):
def floatx():
'''Returns the default float type, as a string
(e.g. 'float16', 'float32', 'float64').
# Returns
String, the current default float type.
# Example
```python
>>> keras.backend.floatx()
'float32'
```
'''
return _FLOATX
def set_floatx(floatx):
'''Sets the default float type.
# Arguments
String: 'float16', 'float32', or 'float64'.
# Example
```python
>>> from keras import backend as K
>>> K.floatx()
'float32'
>>> K.set_floatx('float16')
>>> K.floatx()
'float16'
```
'''
global _FLOATX
if floatx not in {'float16', 'float32', 'float64'}:
raise Exception('Unknown floatx type: ' + str(floatx))
raise ValueError('Unknown floatx type: ' + str(floatx))
_FLOATX = str(floatx)
def cast_to_floatx(x):
'''Cast a Numpy array to floatx.
'''Cast a Numpy array to the default Keras float type.
# Arguments
x: Numpy array.
# Returns
The same Numpy array, cast to its new type.
# Example
```python
>>> from keras import backend as K
>>> K.floatx()
'float32'
>>> arr = numpy.array([1.0, 2.0], dtype='float64')
>>> arr.dtype
dtype('float64')
>>> new_arr = K.cast_to_floatx(arr)
>>> new_arr
array([ 1., 2.], dtype=float32)
>>> new_arr.dtype
dtype('float32')
```
'''
return np.asarray(x, dtype=_FLOATX)
def image_dim_ordering():
'''Returns the image dimension ordering
'''Returns the default image dimension ordering
convention ('th' or 'tf').
# Returns
A string, either `'th'` or `'tf'`
# Example
```python
>>> keras.backend.image_dim_ordering()
'th'
```
'''
return _IMAGE_DIM_ORDERING
@@ -55,14 +131,44 @@ def image_dim_ordering():
def set_image_dim_ordering(dim_ordering):
'''Sets the value of the image dimension
ordering convention ('th' or 'tf').
# Arguments
dim_ordering: string. `'th'` or `'tf'`.
# Example
```python
>>> from keras import backend as K
>>> K.image_dim_ordering()
'th'
>>> K.set_image_dim_ordering('tf')
>>> K.image_dim_ordering()
'tf'
```
'''
global _IMAGE_DIM_ORDERING
if dim_ordering not in {'tf', 'th'}:
raise Exception('Unknown dim_ordering:', dim_ordering)
raise ValueError('Unknown dim_ordering:', dim_ordering)
_IMAGE_DIM_ORDERING = str(dim_ordering)
def get_uid(prefix=''):
'''Provides a unique UID given a string prefix.
# Arguments
prefix: string.
# Returns
An integer.
# Example
```
>>> keras.backend.get_uid('dense')
>>> 1
>>> keras.backend.get_uid('dense')
>>> 2
```
'''
_UID_PREFIXES[prefix] += 1
return _UID_PREFIXES[prefix]
@@ -73,6 +179,28 @@ def reset_uids():
def is_keras_tensor(x):
'''Returns whether `x` is a Keras tensor.
# Arguments
x: a potential tensor.
# Returns
A boolean: whether the argument is a Keras tensor.
# Examples
```python
>>> from keras import backend as K
>>> np_var = numpy.array([1, 2])
>>> K.is_keras_tensor(np_var)
False
>>> keras_var = K.variable(np_var)
>>> K.is_keras_tensor(keras_var) # A variable is not a Tensor.
False
>>> keras_placeholder = K.placeholder(shape=(2, 4, 5))
>>> K.is_keras_tensor(keras_placeholder) # A placeholder is a Tensor.
True
```
'''
if hasattr(x, '_keras_shape'):
return True
else:
Diferenças do arquivo suprimidas por serem muito extensas Carregar Diff
Diferenças do arquivo suprimidas por serem muito extensas Carregar Diff
+330 -53
Ver Arquivo
@@ -1,12 +1,15 @@
from __future__ import absolute_import
from __future__ import print_function
import os
import csv
import numpy as np
import time
import json
import warnings
from collections import deque
from collections import deque, OrderedDict, Iterable
from .utils.generic_utils import Progbar
from keras import backend as K
from pkg_resources import parse_version
@@ -243,17 +246,20 @@ class ModelCheckpoint(Callback):
save_weights_only: if True, then only the model's weights will be
saved (`model.save_weights(filepath)`), else the full model
is saved (`model.save(filepath)`).
period: Interval (number of epochs) between checkpoints.
'''
def __init__(self, filepath, monitor='val_loss', verbose=0,
save_best_only=False, save_weights_only=False,
mode='auto'):
mode='auto', period=1):
super(ModelCheckpoint, self).__init__()
self.monitor = monitor
self.verbose = verbose
self.filepath = filepath
self.save_best_only = save_best_only
self.save_weights_only = save_weights_only
self.period = period
self.epochs_since_last_save = 0
if mode not in ['auto', 'min', 'max']:
warnings.warn('ModelCheckpoint mode %s is unknown, '
@@ -276,35 +282,38 @@ class ModelCheckpoint(Callback):
self.best = np.Inf
def on_epoch_end(self, epoch, logs={}):
filepath = self.filepath.format(epoch=epoch, **logs)
if self.save_best_only:
current = logs.get(self.monitor)
if current is None:
warnings.warn('Can save best model only with %s available, '
'skipping.' % (self.monitor), RuntimeWarning)
else:
if self.monitor_op(current, self.best):
if self.verbose > 0:
print('Epoch %05d: %s improved from %0.5f to %0.5f,'
' saving model to %s'
% (epoch, self.monitor, self.best,
current, filepath))
self.best = current
if self.save_weights_only:
self.model.save_weights(filepath, overwrite=True)
else:
self.model.save(filepath, overwrite=True)
self.epochs_since_last_save += 1
if self.epochs_since_last_save >= self.period:
self.epochs_since_last_save = 0
filepath = self.filepath.format(epoch=epoch, **logs)
if self.save_best_only:
current = logs.get(self.monitor)
if current is None:
warnings.warn('Can save best model only with %s available, '
'skipping.' % (self.monitor), RuntimeWarning)
else:
if self.verbose > 0:
print('Epoch %05d: %s did not improve' %
(epoch, self.monitor))
else:
if self.verbose > 0:
print('Epoch %05d: saving model to %s' % (epoch, filepath))
if self.save_weights_only:
self.model.save_weights(filepath, overwrite=True)
if self.monitor_op(current, self.best):
if self.verbose > 0:
print('Epoch %05d: %s improved from %0.5f to %0.5f,'
' saving model to %s'
% (epoch, self.monitor, self.best,
current, filepath))
self.best = current
if self.save_weights_only:
self.model.save_weights(filepath, overwrite=True)
else:
self.model.save(filepath, overwrite=True)
else:
if self.verbose > 0:
print('Epoch %05d: %s did not improve' %
(epoch, self.monitor))
else:
self.model.save(filepath, overwrite=True)
if self.verbose > 0:
print('Epoch %05d: saving model to %s' % (epoch, filepath))
if self.save_weights_only:
self.model.save_weights(filepath, overwrite=True)
else:
self.model.save(filepath, overwrite=True)
class EarlyStopping(Callback):
@@ -312,22 +321,30 @@ class EarlyStopping(Callback):
# Arguments
monitor: quantity to be monitored.
min_delta: minimum change in the monitored quantity
to qualify as an improvement, i.e. an absolute
change of less than min_delta, will count as no
improvement.
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'):
def __init__(self, monitor='val_loss', min_delta=0, patience=0, verbose=0, mode='auto'):
super(EarlyStopping, self).__init__()
self.monitor = monitor
self.patience = patience
self.verbose = verbose
self.min_delta = min_delta
self.wait = 0
self.stopped_epoch = 0
if mode not in ['auto', 'min', 'max']:
warnings.warn('EarlyStopping mode %s is unknown, '
@@ -345,6 +362,11 @@ class EarlyStopping(Callback):
else:
self.monitor_op = np.less
if self.monitor_op == np.greater:
self.min_delta *= 1
else:
self.min_delta *= -1
def on_train_begin(self, logs={}):
self.wait = 0 # Allow instances to be re-used
self.best = np.Inf if self.monitor_op == np.less else -np.Inf
@@ -355,16 +377,19 @@ class EarlyStopping(Callback):
warnings.warn('Early stopping requires %s available!' %
(self.monitor), RuntimeWarning)
if self.monitor_op(current, self.best):
if self.monitor_op(current - self.min_delta, self.best):
self.best = current
self.wait = 0
else:
if self.wait >= self.patience:
if self.verbose > 0:
print('Epoch %05d: early stopping' % (epoch))
self.stopped_epoch = epoch
self.model.stop_training = True
self.wait += 1
def on_train_end(self, logs={}):
if self.stopped_epoch > 0 and self.verbose > 0:
print('Epoch %05d: early stopping' % (self.stopped_epoch))
class RemoteMonitor(Callback):
'''Callback used to stream events to a server.
@@ -382,11 +407,13 @@ class RemoteMonitor(Callback):
def __init__(self,
root='http://localhost:9000',
path='/publish/epoch/end/',
field='data'):
field='data',
headers={'Accept': 'application/json', 'Content-Type': 'application/json'}):
super(RemoteMonitor, self).__init__()
self.root = root
self.path = path
self.field = field
self.headers = headers
def on_epoch_end(self, epoch, logs={}):
import requests
@@ -396,7 +423,8 @@ class RemoteMonitor(Callback):
send[k] = v
try:
requests.post(self.root + self.path,
{self.field: json.dumps(send)})
{self.field: json.dumps(send)},
headers=self.headers)
except:
print('Warning: could not reach RemoteMonitor '
'root server at ' + str(self.root))
@@ -418,7 +446,11 @@ class LearningRateScheduler(Callback):
assert hasattr(self.model.optimizer, 'lr'), \
'Optimizer must have a "lr" attribute.'
lr = self.schedule(epoch)
assert type(lr) == float, 'The output of the "schedule" function should be float.'
if not isinstance(lr, (float, np.float32, np.float64)):
raise ValueError('The output of the "schedule" function '
'should be float.')
K.set_value(self.model.optimizer.lr, lr)
@@ -451,15 +483,16 @@ 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 '
'with the TensorFlow backend.')
raise RuntimeError('TensorBoard callback only works '
'with the TensorFlow backend.')
self.log_dir = log_dir
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
@@ -468,25 +501,47 @@ 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 parse_version(tf.__version__) >= parse_version('0.12.0'):
self.merged = tf.summary.merge_all()
else:
self.merged = tf.merge_all_summaries()
if self.write_graph:
if parse_version(tf.__version__) >= parse_version('0.8.0'):
if parse_version(tf.__version__) >= parse_version('0.12.0'):
self.writer = tf.summary.FileWriter(self.log_dir,
self.sess.graph)
elif parse_version(tf.__version__) >= parse_version('0.8.0'):
self.writer = tf.train.SummaryWriter(self.log_dir,
self.sess.graph)
else:
self.writer = tf.train.SummaryWriter(self.log_dir,
self.sess.graph_def)
else:
self.writer = tf.train.SummaryWriter(self.log_dir)
if parse_version(tf.__version__) >= parse_version('0.12.0'):
self.writer = tf.summary.FileWriter(self.log_dir)
else:
self.writer = tf.train.SummaryWriter(self.log_dir)
def on_epoch_end(self, epoch, logs={}):
import tensorflow as tf
@@ -512,7 +567,229 @@ class TensorBoard(Callback):
continue
summary = tf.Summary()
summary_value = summary.value.add()
summary_value.simple_value = value
summary_value.simple_value = value.item()
summary_value.tag = name
self.writer.add_summary(summary, epoch)
self.writer.flush()
def on_train_end(self, _):
self.writer.close()
class ReduceLROnPlateau(Callback):
'''Reduce learning rate when a metric has stopped improving.
Models often benefit from reducing the learning rate by a factor
of 2-10 once learning stagnates. This callback monitors a
quantity and if no improvement is seen for a 'patience' number
of epochs, the learning rate is reduced.
# Example
```python
reduce_lr = ReduceLROnPlateau(monitor='val_loss', factor=0.2,
patience=5, min_lr=0.001)
model.fit(X_train, Y_train, callbacks=[reduce_lr])
```
# Arguments
monitor: quantity to be monitored.
factor: factor by which the learning rate will
be reduced. new_lr = lr * factor
patience: number of epochs with no improvement
after which learning rate will be reduced.
verbose: int. 0: quiet, 1: update messages.
mode: one of {auto, min, max}. In `min` mode,
lr will be reduced when the quantity
monitored has stopped decreasing; in `max`
mode it will be reduced when the quantity
monitored has stopped increasing; in `auto`
mode, the direction is automatically inferred
from the name of the monitored quantity.
epsilon: threshold for measuring the new optimum,
to only focus on significant changes.
cooldown: number of epochs to wait before resuming
normal operation after lr has been reduced.
min_lr: lower bound on the learning rate.
'''
def __init__(self, monitor='val_loss', factor=0.1, patience=10,
verbose=0, mode='auto', epsilon=1e-4, cooldown=0, min_lr=0):
super(Callback, self).__init__()
self.monitor = monitor
if factor >= 1.0:
raise ValueError('ReduceLROnPlateau does not support a factor >= 1.0.')
self.factor = factor
self.min_lr = min_lr
self.epsilon = epsilon
self.patience = patience
self.verbose = verbose
self.cooldown = cooldown
self.cooldown_counter = 0 # Cooldown counter.
self.wait = 0
self.best = 0
self.mode = mode
self.monitor_op = None
self.reset()
def reset(self):
if self.mode not in ['auto', 'min', 'max']:
warnings.warn('Learning Rate Plateau Reducing mode %s is unknown, '
'fallback to auto mode.' % (self.mode), RuntimeWarning)
self.mode = 'auto'
if self.mode == 'min' or (self.mode == 'auto' and 'acc' not in self.monitor):
self.monitor_op = lambda a, b: np.less(a, b - self.epsilon)
self.best = np.Inf
else:
self.monitor_op = lambda a, b: np.greater(a, b + self.epsilon)
self.best = -np.Inf
self.cooldown_counter = 0
self.wait = 0
self.lr_epsilon = self.min_lr * 1e-4
def on_train_begin(self, logs={}):
self.reset()
def on_epoch_end(self, epoch, logs={}):
logs['lr'] = K.get_value(self.model.optimizer.lr)
current = logs.get(self.monitor)
if current is None:
warnings.warn('Learning Rate Plateau Reducing requires %s available!' %
self.monitor, RuntimeWarning)
else:
if self.in_cooldown():
self.cooldown_counter -= 1
self.wait = 0
if self.monitor_op(current, self.best):
self.best = current
self.wait = 0
elif not self.in_cooldown():
if self.wait >= self.patience:
old_lr = float(K.get_value(self.model.optimizer.lr))
if old_lr > self.min_lr + self.lr_epsilon:
new_lr = old_lr * self.factor
new_lr = max(new_lr, self.min_lr)
K.set_value(self.model.optimizer.lr, new_lr)
if self.verbose > 0:
print('\nEpoch %05d: reducing learning rate to %s.' % (epoch, new_lr))
self.cooldown_counter = self.cooldown
self.wait = 0
self.wait += 1
def in_cooldown(self):
return self.cooldown_counter > 0
class CSVLogger(Callback):
'''Callback that streams epoch results to a csv file.
Supports all values that can be represented as a string,
including 1D iterables such as np.ndarray.
# Example
```python
csv_logger = CSVLogger('training.log')
model.fit(X_train, Y_train, callbacks=[csv_logger])
```
# Arguments
filename: filename of the csv file, e.g. 'run/log.csv'.
separator: string used to separate elements in the csv file.
append: True: append if file exists (useful for continuing
training). False: overwrite existing file,
'''
def __init__(self, filename, separator=',', append=False):
self.sep = separator
self.filename = filename
self.append = append
self.writer = None
self.keys = None
self.append_header = True
super(CSVLogger, self).__init__()
def on_train_begin(self, logs={}):
if self.append:
if os.path.exists(self.filename):
with open(self.filename) as f:
self.append_header = len(f.readline()) == 0
self.csv_file = open(self.filename, 'a')
else:
self.csv_file = open(self.filename, 'w')
def on_epoch_end(self, epoch, logs={}):
def handle_value(k):
is_zero_dim_ndarray = isinstance(k, np.ndarray) and k.ndim == 0
if isinstance(k, Iterable) and not is_zero_dim_ndarray:
return '"[%s]"' % (', '.join(map(lambda x: str(x), k)))
else:
return k
if not self.writer:
self.keys = sorted(logs.keys())
self.writer = csv.DictWriter(self.csv_file, fieldnames=['epoch'] + self.keys)
if self.append_header:
self.writer.writeheader()
row_dict = OrderedDict({'epoch': epoch})
row_dict.update((key, handle_value(logs[key])) for key in self.keys)
self.writer.writerow(row_dict)
self.csv_file.flush()
def on_train_end(self, logs={}):
self.csv_file.close()
class LambdaCallback(Callback):
"""Callback for creating simple, custom callbacks on-the-fly.
This callback is constructed with anonymous functions that will be called
at the appropriate time. Note that the callbacks expects positional
arguments, as:
- `on_epoch_begin` and `on_epoch_end` expect two positional arguments: `epoch`, `logs`
- `on_batch_begin` and `on_batch_end` expect two positional arguments: `batch`, `logs`
- `on_train_begin` and `on_train_end` expect one positional argument: `logs`
# Arguments
on_epoch_begin: called at the beginning of every epoch.
on_epoch_end: called at the end of every epoch.
on_batch_begin: called at the beginning of every batch.
on_batch_end: called at the end of every batch.
on_train_begin: called at the beginning of model training.
on_train_end: called at the end of model training.
# Example
```python
# Print the batch number at the beginning of every batch.
batch_print_callback = LambdaCallback(on_batch_begin=lambda batch, logs: print(batch))
# Plot the loss after every epoch.
import numpy as np
import matplotlib.pyplot as plt
plot_loss_callback = LambdaCallback(on_epoch_end=lambda epoch, logs: plt.plot(np.arange(epoch), logs['loss']))
# Terminate some processes after having finished model training.
processes = ...
cleanup_callback = LambdaCallback(on_train_end=lambda logs: [p.terminate() for p in processes if p.is_alive()])
model.fit(..., callbacks=[batch_print_callback, plot_loss_callback, cleanup_callback])
```
"""
def __init__(self,
on_epoch_begin=None,
on_epoch_end=None,
on_batch_begin=None,
on_batch_end=None,
on_train_begin=None,
on_train_end=None,
**kwargs):
super(Callback, self).__init__()
self.__dict__.update(kwargs)
self.on_epoch_begin = on_epoch_begin if on_epoch_begin else lambda epoch, logs: None
self.on_epoch_end = on_epoch_end if on_epoch_end else lambda epoch, logs: None
self.on_batch_begin = on_batch_begin if on_batch_begin else lambda batch, logs: None
self.on_batch_end = on_batch_end if on_batch_end else lambda batch, logs: None
self.on_train_begin = on_train_begin if on_train_begin else lambda logs: None
self.on_train_end = on_train_end if on_train_end else lambda logs: None
+3 -2
Ver Arquivo
@@ -11,9 +11,10 @@ def load_batch(fpath, label_key='labels'):
else:
d = cPickle.load(f, encoding="bytes")
# decode utf8
d_decoded = {}
for k, v in d.items():
del(d[k])
d[k.decode("utf8")] = v
d_decoded[k.decode("utf8")] = v
d = d_decoded
f.close()
data = d["data"]
labels = d[label_key]
+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)
+10 -8
Ver Arquivo
@@ -1,28 +1,30 @@
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
def load_data(label_mode='fine'):
if label_mode not in ['fine', 'coarse']:
raise Exception('label_mode must be one of "fine" "coarse".')
raise ValueError('label_mode must be one of "fine" "coarse".')
dirname = "cifar-100-python"
origin = "http://www.cs.toronto.edu/~kriz/cifar-100-python.tar.gz"
dirname = 'cifar-100-python'
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')
X_train, y_train = load_batch(fpath, label_key=label_mode + '_labels')
fpath = os.path.join(path, 'test')
X_test, y_test = load_batch(fpath, label_key=label_mode+'_labels')
X_test, y_test = load_batch(fpath, label_key=label_mode + '_labels')
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 -4
Ver Arquivo
@@ -10,7 +10,8 @@ import sys
def load_data(path='imdb_full.pkl', nb_words=None, skip_top=0,
maxlen=None, seed=113,
start_char=1, oov_char=2, index_from=3):
'''
'''Loads IMDB dataset.
# Arguments
path: where to store the data (in `/.keras/dataset`)
nb_words: max number of words to include. Words are ranked
@@ -72,9 +73,9 @@ def load_data(path='imdb_full.pkl', nb_words=None, skip_top=0,
X = new_X
labels = new_labels
if not X:
raise Exception('After filtering for sequences shorter than maxlen=' +
str(maxlen) + ', no sequence was kept. '
'Increase maxlen.')
raise ValueError('After filtering for sequences shorter than maxlen=' +
str(maxlen) + ', no sequence was kept. '
'Increase maxlen.')
if not nb_words:
nb_words = max([max(x) for x in X])
+4 -5
Ver Arquivo
@@ -1,14 +1,13 @@
# -*- coding: utf-8 -*-
import gzip
from ..utils.data_utils import get_file
from six.moves import cPickle
import sys
def load_data(path="mnist.pkl.gz"):
path = get_file(path, origin="https://s3.amazonaws.com/img-datasets/mnist.pkl.gz")
def load_data(path='mnist.pkl.gz'):
path = get_file(path, origin='https://s3.amazonaws.com/img-datasets/mnist.pkl.gz')
if path.endswith(".gz"):
if path.endswith('.gz'):
f = gzip.open(path, 'rb')
else:
f = open(path, 'rb')
@@ -16,7 +15,7 @@ def load_data(path="mnist.pkl.gz"):
if sys.version_info < (3,):
data = cPickle.load(f)
else:
data = cPickle.load(f, encoding="bytes")
data = cPickle.load(f, encoding='bytes')
f.close()
return data # (X_train, y_train), (X_test, y_test)
+2 -1
Ver Arquivo
@@ -10,7 +10,8 @@ import sys
def load_data(path='reuters.pkl', nb_words=None, skip_top=0,
maxlen=None, test_split=0.2, seed=113,
start_char=1, oov_char=2, index_from=3):
'''
'''Loads the Reuters newswire classification dataset.
# Arguments
path: where to store the data (in `/.keras/dataset`)
nb_words: max number of words to include. Words are ranked
+874 -599
Ver Arquivo
Diferenças do arquivo suprimidas por serem muito extensas Carregar Diff
+458 -359
Ver Arquivo
Diferenças do arquivo suprimidas por serem muito extensas Carregar Diff
+4 -4
Ver Arquivo
@@ -1,6 +1,7 @@
from __future__ import absolute_import
import numpy as np
from . import backend as K
from .utils.generic_utils import get_from_module
def get_fans(shape, dim_ordering='th'):
@@ -20,7 +21,7 @@ def get_fans(shape, dim_ordering='th'):
fan_in = shape[-2] * receptive_field_size
fan_out = shape[-1] * receptive_field_size
else:
raise Exception('Invalid dim_ordering: ' + dim_ordering)
raise ValueError('Invalid dim_ordering: ' + dim_ordering)
else:
# no specific assumptions
fan_in = np.sqrt(np.prod(shape))
@@ -87,8 +88,8 @@ def orthogonal(shape, scale=1.1, name=None):
def identity(shape, scale=1, name=None):
if len(shape) != 2 or shape[0] != shape[1]:
raise Exception('Identity matrix initialization can only be used '
'for 2D square matrices.')
raise ValueError('Identity matrix initialization can only be used '
'for 2D square matrices.')
else:
return K.variable(scale * np.identity(shape[0]), name=name)
@@ -101,7 +102,6 @@ def one(shape, name=None):
return K.ones(shape, name=name)
from .utils.generic_utils import get_from_module
def get(identifier, **kwargs):
return get_from_module(identifier, globals(),
'initialization', kwargs=kwargs)
+1
Ver Arquivo
@@ -10,3 +10,4 @@ from .embeddings import *
from .noise import *
from .advanced_activations import *
from .wrappers import *
from .convolutional_recurrent import *
+90 -21
Ver Arquivo
@@ -52,18 +52,37 @@ class PReLU(Layer):
# Arguments
init: initialization function for the weights.
weights: initial weights, as a list of a single Numpy array.
shared_axes: the axes along which to share learnable
parameters for the activation function.
For example, if the incoming feature maps
are from a 2D convolution
with output shape `(batch, height, width, channels)`,
and you wish to share parameters across space
so that each filter only has one set of parameters,
set `shared_axes=[1, 2]`.
# References
- [Delving Deep into Rectifiers: Surpassing Human-Level Performance on ImageNet Classification](http://arxiv.org/pdf/1502.01852v1.pdf)
'''
def __init__(self, init='zero', weights=None, **kwargs):
def __init__(self, init='zero', weights=None, shared_axes=None, **kwargs):
self.supports_masking = True
self.init = initializations.get(init)
self.initial_weights = weights
if type(shared_axes) is not list and type(shared_axes) is not tuple:
self.shared_axes = [shared_axes]
else:
self.shared_axes = list(shared_axes)
super(PReLU, self).__init__(**kwargs)
def build(self, input_shape):
self.alphas = self.init(input_shape[1:],
param_shape = list(input_shape[1:])
self.param_broadcast = [False] * len(param_shape)
if self.shared_axes[0] is not None:
for i in self.shared_axes:
param_shape[i] = 1
self.param_broadcast[i] = True
self.alphas = self.init(param_shape,
name='{}_alphas'.format(self.name))
self.trainable_weights = [self.alphas]
@@ -73,7 +92,10 @@ class PReLU(Layer):
def call(self, x, mask=None):
pos = K.relu(x)
neg = self.alphas * (x - abs(x)) * 0.5
if K.backend() == 'theano':
neg = K.pattern_broadcast(self.alphas, self.param_broadcast) * (x - abs(x)) * 0.5
else:
neg = self.alphas * (x - abs(x)) * 0.5
return pos + neg
def get_config(self):
@@ -107,9 +129,7 @@ class ELU(Layer):
super(ELU, self).__init__(**kwargs)
def call(self, x, mask=None):
pos = K.relu(x)
neg = (x - abs(x)) * 0.5
return pos + self.alpha * (K.exp(neg) - 1.)
return K.elu(x, self.alpha)
def get_config(self):
config = {'alpha': float(self.alpha)}
@@ -133,23 +153,41 @@ class ParametricSoftplus(Layer):
alpha_init: float. Initial value of the alpha weights.
beta_init: float. Initial values of the beta weights.
weights: initial weights, as a list of 2 numpy arrays.
shared_axes: the axes along which to share learnable
parameters for the activation function.
For example, if the incoming feature maps
are from a 2D convolution
with output shape `(batch, height, width, channels)`,
and you wish to share parameters across space
so that each filter only has one set of parameters,
set `shared_axes=[1, 2]`.
# References
- [Inferring Nonlinear Neuronal Computation Based on Physiologically Plausible Inputs](http://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1003143)
'''
def __init__(self, alpha_init=0.2, beta_init=5.0,
weights=None, **kwargs):
weights=None, shared_axes=None, **kwargs):
self.supports_masking = True
self.alpha_init = K.cast_to_floatx(alpha_init)
self.beta_init = K.cast_to_floatx(beta_init)
self.initial_weights = weights
if type(shared_axes) is not list and type(shared_axes) is not tuple:
self.shared_axes = [shared_axes]
else:
self.shared_axes = list(shared_axes)
super(ParametricSoftplus, self).__init__(**kwargs)
def build(self, input_shape):
input_shape = input_shape[1:]
self.alphas = K.variable(self.alpha_init * np.ones(input_shape),
param_shape = list(input_shape[1:])
self.param_broadcast = [False] * len(param_shape)
if self.shared_axes[0] is not None:
for i in self.shared_axes:
param_shape[i] = 1
self.param_broadcast[i] = True
self.alphas = K.variable(self.alpha_init * np.ones(param_shape),
name='{}_alphas'.format(self.name))
self.betas = K.variable(self.beta_init * np.ones(input_shape),
self.betas = K.variable(self.beta_init * np.ones(param_shape),
name='{}_betas'.format(self.name))
self.trainable_weights = [self.alphas, self.betas]
@@ -158,7 +196,10 @@ class ParametricSoftplus(Layer):
del self.initial_weights
def call(self, x, mask=None):
return K.softplus(self.betas * x) * self.alphas
if K.backend() == 'theano':
return K.softplus(K.pattern_broadcast(self.betas, self.param_broadcast) * x) * K.pattern_broadcast(self.alphas, self.param_broadcast)
else:
return K.softplus(self.betas * x) * self.alphas
def get_config(self):
config = {'alpha_init': float(self.alpha_init),
@@ -216,34 +257,51 @@ class SReLU(Layer):
a_left_init: initialization function for the left part slope
t_right_init: initialization function for the right part intercept
a_right_init: initialization function for the right part slope
shared_axes: the axes along which to share learnable
parameters for the activation function.
For example, if the incoming feature maps
are from a 2D convolution
with output shape `(batch, height, width, channels)`,
and you wish to share parameters across space
so that each filter only has one set of parameters,
set `shared_axes=[1, 2]`.
# References
- [Deep Learning with S-shaped Rectified Linear Activation Units](http://arxiv.org/abs/1512.07030)
'''
def __init__(self, t_left_init='zero', a_left_init='glorot_uniform',
t_right_init='glorot_uniform', a_right_init='one', **kwargs):
t_right_init='glorot_uniform', a_right_init='one', shared_axes=None, **kwargs):
self.supports_masking = True
self.t_left_init = t_left_init
self.a_left_init = a_left_init
self.t_right_init = t_right_init
self.a_right_init = a_right_init
if type(shared_axes) is not list and type(shared_axes) is not tuple:
self.shared_axes = [shared_axes]
else:
self.shared_axes = list(shared_axes)
super(SReLU, self).__init__(**kwargs)
def build(self, input_shape):
input_shape = input_shape[1:]
param_shape = list(input_shape[1:])
self.param_broadcast = [False] * len(param_shape)
if self.shared_axes[0] is not None:
for i in self.shared_axes:
param_shape[i] = 1
self.param_broadcast[i] = True
t_left_init = initializations.get(self.t_left_init)
a_left_init = initializations.get(self.a_left_init)
t_right_init = initializations.get(self.t_right_init)
a_right_init = initializations.get(self.a_right_init)
self.t_left = t_left_init(input_shape,
self.t_left = t_left_init(param_shape,
name='{}_t_left'.format(self.name))
self.a_left = a_left_init(input_shape,
self.a_left = a_left_init(param_shape,
name='{}_a_left'.format(self.name))
self.t_right = t_right_init(input_shape,
self.t_right = t_right_init(param_shape,
name='{}_t_right'.format(self.name))
self.a_right = a_right_init(input_shape,
self.a_right = a_right_init(param_shape,
name='{}_a_right'.format(self.name))
# ensure the the right part is always to the right of the left
self.t_right_actual = self.t_left + abs(self.t_right)
@@ -251,10 +309,21 @@ class SReLU(Layer):
self.t_right, self.a_right]
def call(self, x, mask=None):
Y_left_and_center = self.t_left + K.relu(x - self.t_left,
self.a_left,
self.t_right_actual - self.t_left)
Y_right = K.relu(x - self.t_right_actual) * self.a_right
if K.backend() == 'theano':
t_left = K.pattern_broadcast(self.t_left, self.param_broadcast)
a_left = K.pattern_broadcast(self.a_left, self.param_broadcast)
a_right = K.pattern_broadcast(self.a_right, self.param_broadcast)
t_right_actual = K.pattern_broadcast(self.t_right_actual, self.param_broadcast)
else:
t_left = self.t_left
a_left = self.a_left
a_right = self.a_right
t_right_actual = self.t_right_actual
Y_left_and_center = t_left + K.relu(x - t_left,
a_left,
t_right_actual - t_left)
Y_right = K.relu(x - t_right_actual) * a_right
return Y_left_and_center + Y_right
def get_config(self):
Diferenças do arquivo suprimidas por serem muito extensas Carregar Diff
+510
Ver Arquivo
@@ -0,0 +1,510 @@
from .. import backend as K
from .. import activations, initializations, regularizers
import numpy as np
from ..engine import Layer, InputSpec
from ..utils.np_utils import conv_output_length
import warnings
class ConvRecurrent2D(Layer):
'''Abstract base class for convolutional recurrent layers.
Do not use in a model -- it's not a functional layer!
ConvLSTM2D
follow the specifications of this class and accept
the keyword arguments listed below.
# Input shape
5D tensor with shape `(nb_samples, timesteps, channels, rows, cols)`.
# Output shape
- if `return_sequences`: 5D tensor with shape
`(nb_samples, timesteps, channels, rows, cols)`.
- else, 4D tensor with shape `(nb_samples, channels, rows, cols)`.
# Arguments
weights: list of numpy arrays to set as initial weights.
The list should have 3 elements, of shapes:
`[(input_dim, nb_filter), (nb_filter, nb_filter), (nb_filter,)]`.
return_sequences: Boolean. Whether to return the last output
in the output sequence, or the full sequence.
go_backwards: Boolean (default False).
If True, rocess the input sequence backwards.
stateful: Boolean (default False). If True, the last state
for each sample at index i in a batch will be used as initial
state for the sample of index i in the following batch.
nb_filter: Number of convolution filters to use.
nb_row: Number of rows in the convolution kernel.
nb_col: Number of columns in the convolution kernel.
is required when using this layer as the first layer in a model.
input_shape: input_shape
# Masking
This layer supports masking for input data with a variable number
of timesteps. To introduce masks to your data,
use an [Embedding](embeddings.md) layer with the `mask_zero` parameter
set to `True`.
**Note:** for the time being, masking is only supported with Theano.
# TensorFlow warning
For the time being, when using the TensorFlow backend,
the number of timesteps used must be specified in your model.
Make sure to pass an `input_length` int argument to your
recurrent layer (if it comes first in your model),
or to pass a complete `input_shape` argument to the first layer
in your model otherwise.
# Note on using statefulness in RNNs
You can set RNN layers to be 'stateful', which means that the states
computed for the samples in one batch will be reused as initial states
for the samples in the next batch.
This assumes a one-to-one mapping between
samples in different successive batches.
To enable statefulness:
- specify `stateful=True` in the layer constructor.
- specify a fixed batch size for your model, by passing
a `batch_input_size=(...)` to the first layer in your model.
This is the expected shape of your inputs *including the batch
size*.
It should be a tuple of integers, e.g. `(32, 10, 100)`.
To reset the states of your model, call `.reset_states()` on either
a specific layer, or on your entire model.
'''
def __init__(self, weights=None, nb_row=None, nb_col=None, nb_filter=None,
return_sequences=False, go_backwards=False, stateful=False,
dim_ordering=None, **kwargs):
self.return_sequences = return_sequences
self.go_backwards = go_backwards
self.stateful = stateful
self.initial_weights = weights
self.nb_row = nb_row
self.nb_col = nb_col
self.nb_filter = nb_filter
self.dim_ordering = dim_ordering
self.input_spec = [InputSpec(ndim=5)]
super(ConvRecurrent2D, self).__init__(**kwargs)
def compute_mask(self, input, mask):
if self.return_sequences:
return mask
else:
return None
def get_output_shape_for(self, input_shape):
if self.dim_ordering == 'th':
rows = input_shape[3]
cols = input_shape[4]
elif self.dim_ordering == 'tf':
rows = input_shape[2]
cols = input_shape[3]
else:
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
rows = conv_output_length(rows, self.nb_row,
self.border_mode, self.subsample[0])
cols = conv_output_length(cols, self.nb_col,
self.border_mode, self.subsample[1])
if self.return_sequences:
if self.dim_ordering == 'th':
return (input_shape[0], input_shape[1],
self.nb_filter, rows, cols)
elif self.dim_ordering == 'tf':
return (input_shape[0], input_shape[1],
rows, cols, self.nb_filter)
else:
if self.dim_ordering == 'th':
return (input_shape[0], self.nb_filter, rows, cols)
elif self.dim_ordering == 'tf':
return (input_shape[0], rows, cols, self.nb_filter)
def step(self, x, states):
raise NotImplementedError
def get_constants(self, X, train=False):
return None
def get_initial_states(self, X):
# (samples, timesteps, row, col, filter)
initial_state = K.zeros_like(X)
# (samples,row, col, filter)
initial_state = K.sum(initial_state, axis=1)
initial_state = self.conv_step(initial_state, K.zeros(self.W_shape),
border_mode=self.border_mode)
initial_states = [initial_state for _ in range(2)]
return initial_states
def preprocess_input(self, x):
return x
def call(self, x, mask=None):
assert K.ndim(x) == 5
input_shape = self.input_spec[0].shape
unroll = False
if self.stateful:
initial_states = self.states
else:
initial_states = self.get_initial_states(x)
constants = self.get_constants(x)
preprocessed_input = self.preprocess_input(x)
last_output, outputs, states = K.rnn(self.step, preprocessed_input,
initial_states,
go_backwards=self.go_backwards,
mask=mask,
constants=constants,
unroll=unroll,
input_length=input_shape[1])
if self.stateful:
self.updates = []
for i in range(len(states)):
self.updates.append((self.states[i], states[i]))
if self.return_sequences:
return outputs
else:
return last_output
def get_config(self):
config = {'return_sequences': self.return_sequences,
'go_backwards': self.go_backwards,
'stateful': self.stateful}
if self.stateful:
config['batch_input_shape'] = self.input_spec[0].shape
base_config = super(ConvRecurrent2D, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class ConvLSTM2D(ConvRecurrent2D):
'''Convolutional LSTM.
# Input shape
- if dim_ordering='th'
5D tensor with shape:
`(samples,time, channels, rows, cols)`
- if dim_ordering='tf'
5D tensor with shape:
`(samples,time, rows, cols, channels)`
# Output shape
- if `return_sequences`
- if dim_ordering='th'
5D tensor with shape:
`(samples, time, nb_filter, output_row, output_col)`
- if dim_ordering='tf'
5D tensor with shape:
`(samples, time, output_row, output_col, nb_filter)`
- else
- if dim_ordering ='th'
4D tensor with shape:
`(samples, nb_filter, output_row, output_col)`
- if dim_ordering='tf'
4D tensor with shape:
`(samples, output_row, output_col, nb_filter)`
where o_row and o_col depend on the shape of the filter and
the border_mode
# Arguments
nb_filter: Number of convolution filters to use.
nb_row: Number of rows in the convolution kernel.
nb_col: Number of columns in the convolution kernel.
border_mode: 'valid' or 'same'.
subsample: tuple of length 2. Factor by which to subsample output.
Also called strides elsewhere.
dim_ordering: 'tf' if the feature are at the last dimension or 'th'
stateful : Boolean (default False). If True, the last state
for each sample at index i in a batch will be used as initial
state for the sample of index i in the following batch.
init: weight initialization function.
Can be the name of an existing function (str),
or a Theano function
(see: [initializations](../initializations.md)).
inner_init: initialization function of the inner cells.
forget_bias_init: initialization function for the bias of the
forget gate.
[Jozefowicz et al.](http://www.jmlr.org/proceedings/papers/v37/jozefowicz15.pdf)
recommend initializing with ones.
activation: activation function.
Can be the name of an existing function (str),
or a Theano function (see: [activations](../activations.md)).
inner_activation: activation function for the inner cells.
# References
- [Convolutional LSTM Network: A Machine Learning Approach for
Precipitation Nowcasting](http://arxiv.org/pdf/1506.04214v1.pdf)
The current implementation does not include the feedback loop on the
cells output
'''
def __init__(self, nb_filter, nb_row, nb_col,
init='glorot_uniform', inner_init='orthogonal',
forget_bias_init='one', activation='tanh',
inner_activation='hard_sigmoid',
dim_ordering='default',
border_mode='valid', subsample=(1, 1),
W_regularizer=None, U_regularizer=None, b_regularizer=None,
dropout_W=0., dropout_U=0., **kwargs):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
if dim_ordering not in {'tf', 'th'}:
raise ValueError('dim_ordering must be in {tf,th}', dim_ordering)
self.nb_filter = nb_filter
self.nb_row = nb_row
self.nb_col = nb_col
self.init = initializations.get(init)
self.inner_init = initializations.get(inner_init)
self.forget_bias_init = initializations.get(forget_bias_init)
self.activation = activations.get(activation)
self.inner_activation = activations.get(inner_activation)
self.border_mode = border_mode
self.subsample = subsample
if dim_ordering == 'th':
warnings.warn('Be carefull if used with convolution3D layers:\n'
'th in convolution 3D corresponds to '
'(samples, channels, conv_dim1, conv_dim2,'
'conv_dim3)\n'
'while for this network it corresponds to: '
'(samples, time, channels, rows, cols)')
self.dim_ordering = dim_ordering
kwargs['nb_filter'] = nb_filter
kwargs['nb_row'] = nb_row
kwargs['nb_col'] = nb_col
kwargs['dim_ordering'] = dim_ordering
self.W_regularizer = regularizers.get(W_regularizer)
self.U_regularizer = regularizers.get(U_regularizer)
self.b_regularizer = regularizers.get(b_regularizer)
self.dropout_W, self.dropout_U = dropout_W, dropout_U
if self.dropout_W or self.dropout_U:
self.uses_learning_phase = True
super(ConvLSTM2D, self).__init__(**kwargs)
def build(self, input_shape):
self.input_spec = [InputSpec(shape=input_shape)]
if self.dim_ordering == 'th':
stack_size = input_shape[2]
self.W_shape = (self.nb_filter, stack_size,
self.nb_row, self.nb_col)
elif self.dim_ordering == 'tf':
stack_size = input_shape[4]
self.W_shape = (self.nb_row, self.nb_col,
stack_size, self.nb_filter)
else:
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
if self.dim_ordering == 'th':
self.W_shape1 = (self.nb_filter, self.nb_filter,
self.nb_row, self.nb_col)
elif self.dim_ordering == 'tf':
self.W_shape1 = (self.nb_row, self.nb_col,
self.nb_filter, self.nb_filter)
if self.stateful:
self.reset_states()
else:
# initial states: 2 all-zero tensor of shape (nb_filter)
self.states = [None, None, None, None]
self.W_i = self.init(self.W_shape, name='{}_W_i'.format(self.name))
self.U_i = self.inner_init(self.W_shape1,
name='{}_U_i'.format(self.name))
self.b_i = K.zeros((self.nb_filter,), name='{}_b_i'.format(self.name))
self.W_f = self.init(self.W_shape, name='{}_W_f'.format(self.name))
self.U_f = self.inner_init(self.W_shape1,
name='{}_U_f'.format(self.name))
self.b_f = self.forget_bias_init((self.nb_filter,),
name='{}_b_f'.format(self.name))
self.W_c = self.init(self.W_shape, name='{}_W_c'.format(self.name))
self.U_c = self.inner_init(self.W_shape1,
name='{}_U_c'.format(self.name))
self.b_c = K.zeros((self.nb_filter,), name='{}_b_c'.format(self.name))
self.W_o = self.init(self.W_shape, name='{}_W_o'.format(self.name))
self.U_o = self.inner_init(self.W_shape1,
name='{}_U_o'.format(self.name))
self.b_o = K.zeros((self.nb_filter,), name='{}_b_o'.format(self.name))
self.trainable_weights = [self.W_i, self.U_i, self.b_i,
self.W_c, self.U_c, self.b_c,
self.W_f, self.U_f, self.b_f,
self.W_o, self.U_o, self.b_o]
self.W = K.concatenate([self.W_i, self.W_f, self.W_c, self.W_o])
self.U = K.concatenate([self.U_i, self.U_f, self.U_c, self.U_o])
self.b = K.concatenate([self.b_i, self.b_f, self.b_c, self.b_o])
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.U_regularizer:
self.U_regularizer.set_param(self.U)
self.regularizers.append(self.U_regularizer)
if self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def reset_states(self):
assert self.stateful, 'Layer must be stateful.'
input_shape = self.input_spec[0].shape
output_shape = self.get_output_shape_for(input_shape)
if not input_shape[0]:
raise ValueError('If a RNN is stateful, a complete ' +
'input_shape must be provided ' +
'(including batch size).')
if self.return_sequences:
out_row, out_col, out_filter = output_shape[2:]
else:
out_row, out_col, out_filter = output_shape[1:]
if hasattr(self, 'states'):
K.set_value(self.states[0],
np.zeros((input_shape[0],
out_row, out_col, out_filter)))
K.set_value(self.states[1],
np.zeros((input_shape[0],
out_row, out_col, out_filter)))
else:
self.states = [K.zeros((input_shape[0],
out_row, out_col, out_filter)),
K.zeros((input_shape[0],
out_row, out_col, out_filter))]
def conv_step(self, x, W, b=None, border_mode='valid'):
input_shape = self.input_spec[0].shape
conv_out = K.conv2d(x, W, strides=self.subsample,
border_mode=border_mode,
dim_ordering=self.dim_ordering,
image_shape=(input_shape[0],
input_shape[2],
input_shape[3],
input_shape[4]),
filter_shape=self.W_shape)
if b:
if self.dim_ordering == 'th':
conv_out = conv_out + K.reshape(b, (1, self.nb_filter, 1, 1))
elif self.dim_ordering == 'tf':
conv_out = conv_out + K.reshape(b, (1, 1, 1, self.nb_filter))
else:
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
return conv_out
def conv_step_hidden(self, x, W, border_mode='valid'):
# This new function was defined because the
# image shape must be hardcoded
input_shape = self.input_spec[0].shape
output_shape = self.get_output_shape_for(input_shape)
if self.return_sequences:
out_row, out_col, out_filter = output_shape[2:]
else:
out_row, out_col, out_filter = output_shape[1:]
conv_out = K.conv2d(x, W, strides=(1, 1),
border_mode=border_mode,
dim_ordering=self.dim_ordering,
image_shape=(input_shape[0],
out_row, out_col,
out_filter),
filter_shape=self.W_shape1)
return conv_out
def step(self, x, states):
assert len(states) == 4
h_tm1 = states[0]
c_tm1 = states[1]
B_U = states[2]
B_W = states[3]
x_i = self.conv_step(x * B_W[0], self.W_i, self.b_i,
border_mode=self.border_mode)
x_f = self.conv_step(x * B_W[1], self.W_f, self.b_f,
border_mode=self.border_mode)
x_c = self.conv_step(x * B_W[2], self.W_c, self.b_c,
border_mode=self.border_mode)
x_o = self.conv_step(x * B_W[3], self.W_o, self.b_o,
border_mode=self.border_mode)
# U : from nb_filter to nb_filter
# Same because must be stable in the output space
h_i = self.conv_step_hidden(h_tm1 * B_U[0], self.U_i,
border_mode='same')
h_f = self.conv_step_hidden(h_tm1 * B_U[1], self.U_f,
border_mode='same')
h_c = self.conv_step_hidden(h_tm1 * B_U[2], self.U_c,
border_mode='same')
h_o = self.conv_step_hidden(h_tm1 * B_U[3], self.U_o,
border_mode='same')
i = self.inner_activation(x_i + h_i)
f = self.inner_activation(x_f + h_f)
c = f * c_tm1 + i * self.activation(x_c + h_c)
o = self.inner_activation(x_o + h_o)
h = o * self.activation(c)
return h, [h, c]
def get_constants(self, x):
constants = []
if 0 < self.dropout_U < 1:
ones = K.zeros_like(x)
ones = K.sum(ones, axis=1)
ones = self.conv_step(ones, K.zeros(self.W_shape),
border_mode=self.border_mode)
ones = ones + 1
B_U = [K.in_train_phase(K.dropout(ones, self.dropout_U), ones)
for _ in range(4)]
constants.append(B_U)
else:
constants.append([K.cast_to_floatx(1.) for _ in range(4)])
if 0 < self.dropout_W < 1:
ones = K.zeros_like(x)
ones = K.sum(ones, axis=1)
ones = ones + 1
B_W = [K.in_train_phase(K.dropout(ones, self.dropout_W), ones)
for _ in range(4)]
constants.append(B_W)
else:
constants.append([K.cast_to_floatx(1.) for _ in range(4)])
return constants
def get_config(self):
config = {'nb_filter': self.nb_filter,
'nb_row': self.nb_row,
'nb_col': self.nb_col,
'init': self.init.__name__,
'inner_init': self.inner_init.__name__,
'forget_bias_init': self.forget_bias_init.__name__,
'activation': self.activation.__name__,
'dim_ordering': self.dim_ordering,
'border_mode': self.border_mode,
'inner_activation': self.inner_activation.__name__}
base_config = super(ConvLSTM2D, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
+222 -197
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):
@@ -97,6 +96,37 @@ class Dropout(Layer):
return dict(list(base_config.items()) + list(config.items()))
class SpatialDropout1D(Dropout):
'''This version performs the same function as Dropout, however it drops
entire 1D feature maps instead of individual elements. If adjacent frames
within feature maps are strongly correlated (as is normally the case in
early convolution layers) then regular dropout will not regularize the
activations and will otherwise just result in an effective learning rate
decrease. In this case, SpatialDropout1D will help promote independence
between feature maps and should be used instead.
# Arguments
p: float between 0 and 1. Fraction of the input units to drop.
# Input shape
3D tensor with shape:
`(samples, timesteps, channels)`
# Output shape
Same as input
# References
- [Efficient Object Localization Using Convolutional Networks](https://arxiv.org/pdf/1411.4280.pdf)
'''
def __init__(self, p, **kwargs):
super(SpatialDropout1D, self).__init__(p, **kwargs)
def _get_noise_shape(self, x):
input_shape = K.shape(x)
noise_shape = (input_shape[0], 1, input_shape[2])
return noise_shape
class SpatialDropout2D(Dropout):
'''This version performs the same function as Dropout, however it drops
entire 2D feature maps instead of individual elements. If adjacent pixels
@@ -112,7 +142,7 @@ class SpatialDropout2D(Dropout):
(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".
If you never set it, then it will be "tf".
# Input shape
4D tensor with shape:
@@ -140,7 +170,7 @@ class SpatialDropout2D(Dropout):
elif self.dim_ordering == 'tf':
noise_shape = (input_shape[0], 1, 1, input_shape[3])
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
return noise_shape
@@ -160,7 +190,7 @@ class SpatialDropout3D(Dropout):
is at index 1, in 'tf' mode is it at index 4.
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".
If you never set it, then it will be "tf".
# Input shape
5D tensor with shape:
@@ -188,7 +218,7 @@ class SpatialDropout3D(Dropout):
elif self.dim_ordering == 'tf':
noise_shape = (input_shape[0], 1, 1, 1, input_shape[4])
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
return noise_shape
@@ -260,8 +290,8 @@ class Reshape(Layer):
'''Find and replace a single missing dimension in an output shape
given an input shape.
A near direct port of the internal Numpy function _fix_unknown_dimension
in numpy/core/src/multiarray/shape.c
A near direct port of the internal Numpy function
_fix_unknown_dimension in numpy/core/src/multiarray/shape.c
# Arguments
input_shape: shape of array being reshaped
@@ -302,7 +332,8 @@ class Reshape(Layer):
return tuple(output_shape)
def get_output_shape_for(self, input_shape):
return (input_shape[0],) + self._fix_unknown_dimension(input_shape[1:], self.target_shape)
return (input_shape[0],) + self._fix_unknown_dimension(input_shape[1:],
self.target_shape)
def call(self, x, mask=None):
# In case the target shape is not fully defined,
@@ -385,7 +416,9 @@ class Flatten(Layer):
```python
model = Sequential()
model.add(Convolution2D(64, 3, 3, border_mode='same', input_shape=(3, 32, 32)))
model.add(Convolution2D(64, 3, 3,
border_mode='same',
input_shape=(3, 32, 32)))
# now: model.output_shape == (None, 64, 32, 32)
model.add(Flatten())
@@ -398,12 +431,12 @@ class Flatten(Layer):
def get_output_shape_for(self, input_shape):
if not all(input_shape[1:]):
raise Exception('The shape of the input to "Flatten" '
'is not fully defined '
'(got ' + str(input_shape[1:]) + '. '
'Make sure to pass a complete "input_shape" '
'or "batch_input_shape" argument to the first '
'layer in your model.')
raise ValueError('The shape of the input to "Flatten" '
'is not fully defined '
'(got ' + str(input_shape[1:]) + '. '
'Make sure to pass a complete "input_shape" '
'or "batch_input_shape" argument to the first '
'layer in your model.')
return (input_shape[0], np.prod(input_shape[1:]))
def call(self, x, mask=None):
@@ -479,21 +512,22 @@ class Lambda(Layer):
shape[-1] *= 2
return tuple(shape)
model.add(Lambda(antirectifier, output_shape=antirectifier_output_shape))
model.add(Lambda(antirectifier,
output_shape=antirectifier_output_shape))
```
# 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.
@@ -512,38 +546,46 @@ class Lambda(Layer):
if output_shape is None:
self._output_shape = None
elif type(output_shape) in {tuple, list}:
elif isinstance(output_shape, (tuple, list)):
self._output_shape = tuple(output_shape)
else:
if not hasattr(output_shape, '__call__'):
raise Exception('In Lambda, `output_shape` '
if not callable(output_shape):
raise TypeError('In Lambda, `output_shape` '
'must be a list, a tuple, or a function.')
self._output_shape = output_shape
super(Lambda, self).__init__(**kwargs)
def get_output_shape_for(self, input_shape):
if self._output_shape is None:
# if TensorFlow, we can infer the output shape directly:
if K._BACKEND == 'tensorflow':
if type(input_shape) is list:
# With TensorFlow, we can infer the output shape directly:
if K.backend() == 'tensorflow':
if isinstance(input_shape, list):
xs = [K.placeholder(shape=shape) for shape in input_shape]
x = self.call(xs)
else:
x = K.placeholder(shape=input_shape)
x = self.call(x)
if type(x) is list:
if isinstance(x, list):
return [K.int_shape(x_elem) for x_elem in x]
else:
return K.int_shape(x)
# otherwise, we default to the input shape
# Otherwise, we default to the input shape.
warnings.warn('`output_shape` argument not specified for layer {} '
'and cannot be automatically inferred with the Theano backend. '
'Defaulting to output shape `{}` (same as input shape). '
'If the expected output shape is different, specify it via the `output_shape` argument.'
.format(self.name, input_shape))
return input_shape
elif type(self._output_shape) in {tuple, list}:
nb_samples = input_shape[0] if input_shape else None
elif isinstance(self._output_shape, (tuple, list)):
if isinstance(input_shape, 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)
if type(shape) not in {list, tuple}:
raise Exception('output_shape function must return a tuple')
if not isinstance(shape, (list, tuple)):
raise ValueError('output_shape function must return a tuple')
return tuple(shape)
def call(self, x, mask=None):
@@ -554,23 +596,15 @@ 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__
@@ -588,22 +622,27 @@ class Lambda(Layer):
return dict(list(base_config.items()) + list(config.items()))
@classmethod
def from_config(cls, config):
def from_config(cls, config, custom_objects={}):
# Insert custom objects into globals.
if custom_objects:
globs = globals().copy()
globs.update(custom_objects)
else:
globs = globals()
function_type = config.pop('function_type')
if function_type == 'function':
function = globals()[config['function']]
function = globs[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=globs)
else:
raise Exception('Unknown function type: ' + function_type)
raise TypeError('Unknown function type:', function_type)
output_shape_type = config.pop('output_shape_type')
if output_shape_type == 'function':
output_shape = globals()[config['output_shape']]
output_shape = globs[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=globs)
else:
output_shape = config['output_shape']
@@ -658,18 +697,24 @@ class Dense(Layer):
(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: dimensionality of the input (integer).
This argument (or alternatively, the keyword argument `input_shape`)
bias: whether to include a bias
(i.e. make the layer affine rather than linear).
input_dim: dimensionality of the input (integer). This argument
(or alternatively, the keyword argument `input_shape`)
is required when using this layer as the first layer in a model.
# Input shape
2D tensor with shape: `(nb_samples, input_dim)`.
nD tensor with shape: `(nb_samples, ..., input_dim)`.
The most common situation would be
a 2D input with shape `(nb_samples, input_dim)`.
# Output shape
2D tensor with shape: `(nb_samples, output_dim)`.
nD tensor with shape: `(nb_samples, ..., output_dim)`.
For instance, for a 2D input with shape `(nb_samples, input_dim)`,
the output would have shape `(nb_samples, output_dim)`.
'''
def __init__(self, output_dim, init='glorot_uniform', activation='linear', weights=None,
def __init__(self, output_dim, init='glorot_uniform',
activation=None, weights=None,
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, input_dim=None, **kwargs):
@@ -687,49 +732,37 @@ class Dense(Layer):
self.bias = bias
self.initial_weights = weights
self.input_spec = [InputSpec(ndim=2)]
self.input_spec = [InputSpec(ndim='2+')]
if self.input_dim:
kwargs['input_shape'] = (self.input_dim,)
super(Dense, self).__init__(**kwargs)
def build(self, input_shape):
assert len(input_shape) == 2
input_dim = input_shape[1]
assert len(input_shape) >= 2
input_dim = input_shape[-1]
self.input_dim = input_dim
self.input_spec = [InputSpec(dtype=K.floatx(),
shape=(None, input_dim))]
ndim='2+')]
self.W = self.init((input_dim, self.output_dim),
name='{}_W'.format(self.name))
self.W = self.add_weight((input_dim, self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
if self.bias:
self.b = K.zeros((self.output_dim,),
name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.b]
self.b = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer,
constraint=self.b_constraint)
else:
self.trainable_weights = [self.W]
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.bias and self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
if self.bias and self.b_constraint:
self.constraints[self.b] = self.b_constraint
self.b = None
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def call(self, x, mask=None):
output = K.dot(x, self.W)
@@ -738,8 +771,11 @@ class Dense(Layer):
return self.activation(output)
def get_output_shape_for(self, input_shape):
assert input_shape and len(input_shape) == 2
return (input_shape[0], self.output_dim)
assert input_shape and len(input_shape) >= 2
assert input_shape[-1] and input_shape[-1] == self.input_dim
output_shape = list(input_shape)
output_shape[-1] = self.output_dim
return tuple(output_shape)
def get_config(self):
config = {'output_dim': self.output_dim,
@@ -778,9 +814,8 @@ class ActivityRegularization(Layer):
self.l2 = l2
super(ActivityRegularization, self).__init__(**kwargs)
activity_regularizer = ActivityRegularizer(l1=l1, l2=l2)
activity_regularizer.set_layer(self)
self.regularizers = [activity_regularizer]
self.activity_regularizer = regularizers.L1L2Regularizer(l1=l1, l2=l2)
self.regularizers = [self.activity_regularizer]
def get_config(self):
config = {'l1': self.l1,
@@ -823,9 +858,10 @@ class MaxoutDense(Layer):
(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: dimensionality of the input (integer).
This argument (or alternatively, the keyword argument `input_shape`)
bias: whether to include a bias
(i.e. make the layer affine rather than linear).
input_dim: dimensionality of the input (integer). This argument
(or alternatively, the keyword argument `input_shape`)
is required when using this layer as the first layer in a model.
# Input shape
@@ -837,11 +873,18 @@ class MaxoutDense(Layer):
# References
- [Maxout Networks](http://arxiv.org/pdf/1302.4389.pdf)
'''
def __init__(self, output_dim, nb_feature=4,
init='glorot_uniform', weights=None,
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, input_dim=None, **kwargs):
def __init__(self, output_dim,
nb_feature=4,
init='glorot_uniform',
weights=None,
W_regularizer=None,
b_regularizer=None,
activity_regularizer=None,
W_constraint=None,
b_constraint=None,
bias=True,
input_dim=None,
**kwargs):
self.output_dim = output_dim
self.nb_feature = nb_feature
self.init = initializations.get(init)
@@ -867,37 +910,24 @@ class MaxoutDense(Layer):
self.input_spec = [InputSpec(dtype=K.floatx(),
shape=(None, input_dim))]
self.W = self.init((self.nb_feature, input_dim, self.output_dim),
name='{}_W'.format(self.name))
self.W = self.add_weight((self.nb_feature, input_dim, self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
if self.bias:
self.b = K.zeros((self.nb_feature, self.output_dim),
name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.b]
self.b = self.add_weight((self.nb_feature, self.output_dim,),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer,
constraint=self.b_constraint)
else:
self.trainable_weights = [self.W]
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.bias and self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
if self.bias and self.b_constraint:
self.constraints[self.b] = self.b_constraint
self.b = None
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def get_output_shape_for(self, input_shape):
assert input_shape and len(input_shape) == 2
@@ -955,9 +985,10 @@ class Highway(Layer):
(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: dimensionality of the input (integer).
This argument (or alternatively, the keyword argument `input_shape`)
bias: whether to include a bias
(i.e. make the layer affine rather than linear).
input_dim: dimensionality of the input (integer). This argument
(or alternatively, the keyword argument `input_shape`)
is required when using this layer as the first layer in a model.
# Input shape
@@ -969,11 +1000,19 @@ class Highway(Layer):
# References
- [Highway Networks](http://arxiv.org/pdf/1505.00387v2.pdf)
'''
def __init__(self, init='glorot_uniform', transform_bias=-2,
activation='linear', weights=None,
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, input_dim=None, **kwargs):
def __init__(self,
init='glorot_uniform',
transform_bias=-2,
activation=None,
weights=None,
W_regularizer=None,
b_regularizer=None,
activity_regularizer=None,
W_constraint=None,
b_constraint=None,
bias=True,
input_dim=None,
**kwargs):
self.init = initializations.get(init)
self.transform_bias = transform_bias
self.activation = activations.get(activation)
@@ -999,42 +1038,30 @@ class Highway(Layer):
self.input_spec = [InputSpec(dtype=K.floatx(),
shape=(None, input_dim))]
self.W = self.init((input_dim, input_dim),
name='{}_W'.format(self.name))
self.W_carry = self.init((input_dim, input_dim),
name='{}_W_carry'.format(self.name))
self.W = self.add_weight((input_dim, input_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
self.W_carry = self.add_weight((input_dim, input_dim),
initializer=self.init,
name='{}_W_carry'.format(self.name))
if self.bias:
self.b = K.zeros((input_dim,), name='{}_b'.format(self.name))
# initialize with a vector of values `transform_bias`
self.b_carry = K.variable(np.ones((input_dim,)) * self.transform_bias,
name='{}_b_carry'.format(self.name))
self.trainable_weights = [self.W, self.b, self.W_carry, self.b_carry]
self.b = self.add_weight((input_dim,),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer,
constraint=self.b_constraint)
self.b_carry = self.add_weight((input_dim,),
initializer='one',
name='{}_b_carry'.format(self.name))
else:
self.trainable_weights = [self.W, self.W_carry]
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.bias and self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
if self.bias and self.b_constraint:
self.constraints[self.b] = self.b_constraint
self.b_carry = None
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def call(self, x, mask=None):
y = K.dot(x, self.W_carry)
@@ -1104,21 +1131,31 @@ class TimeDistributedDense(Layer):
(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: dimensionality of the input (integer).
This argument (or alternatively, the keyword argument `input_shape`)
bias: whether to include a bias
(i.e. make the layer affine rather than linear).
input_dim: dimensionality of the input (integer). This argument
(or alternatively, the keyword argument `input_shape`)
is required when using this layer as the first layer in a model.
input_length: length of inputs sequences
(integer, or None for variable-length sequences).
'''
def __init__(self, output_dim,
init='glorot_uniform', activation='linear', weights=None,
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, input_dim=None, input_length=None, **kwargs):
warnings.warn('TimeDistributedDense is deprecated, '
'please use TimeDistributed(Dense(...)) instead.')
init='glorot_uniform',
activation=None,
weights=None,
W_regularizer=None,
b_regularizer=None,
activity_regularizer=None,
W_constraint=None,
b_constraint=None,
bias=True,
input_dim=None,
input_length=None,
**kwargs):
warnings.warn('`TimeDistributedDense` is deprecated, '
'And will be removed on May 1st, 2017. '
'Please use a `Dense` layer instead.')
self.output_dim = output_dim
self.init = initializations.get(init)
self.activation = activations.get(activation)
@@ -1146,35 +1183,24 @@ class TimeDistributedDense(Layer):
shape=(None,) + input_shape[1:])]
input_dim = input_shape[2]
self.W = self.init((input_dim, self.output_dim),
name='{}_W'.format(self.name))
self.W = self.add_weight((input_dim, self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
if self.bias:
self.b = K.zeros((self.output_dim,),
name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.b]
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.bias and self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
if self.bias and self.b_constraint:
self.constraints[self.b] = self.b_constraint
self.b = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer,
constraint=self.b_constraint)
else:
self.b = None
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def get_output_shape_for(self, input_shape):
return (input_shape[0], input_shape[1], self.output_dim)
@@ -1183,12 +1209,11 @@ class TimeDistributedDense(Layer):
input_shape = self.input_spec[0].shape
# x has shape (samples, timesteps, input_dim)
input_length = input_shape[1]
# Note: input_length should always be provided when using tensorflow backend.
if not input_length:
if hasattr(K, 'int_shape'):
input_length = K.int_shape(x)[1]
if not input_length:
raise Exception(
raise ValueError(
'Layer ' + self.name +
' requires to know the length of its input, '
'but it could not be inferred automatically. '
+6 -16
Ver Arquivo
@@ -91,25 +91,15 @@ class Embedding(Layer):
super(Embedding, self).__init__(**kwargs)
def build(self, input_shape):
self.W = self.init((self.input_dim, self.output_dim),
name='{}_W'.format(self.name))
self.trainable_weights = [self.W]
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.W = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
self.built = True
def compute_mask(self, x, mask=None):
if not self.mask_zero:
+44 -60
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.
@@ -65,21 +66,23 @@ 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.
'''
def __init__(self, nb_filter, filter_length,
init='uniform', activation='linear', weights=None,
init='glorot_uniform', activation=None, weights=None,
border_mode='valid', subsample_length=1,
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
W_constraint=None, b_constraint=None,
bias=True, input_dim=None, input_length=None, **kwargs):
if border_mode != 'valid':
raise Exception('Invalid border mode for LocallyConnected1D '
'(only "valid" is supported):', border_mode)
raise ValueError('Invalid border mode for LocallyConnected1D '
'(only "valid" is supported):', border_mode)
self.nb_filter = nb_filter
self.filter_length = filter_length
self.init = initializations.get(init, dim_ordering='th')
@@ -107,35 +110,27 @@ class LocallyConnected1D(Layer):
def build(self, input_shape):
input_dim = input_shape[2]
_, output_length, nb_filter = self.get_output_shape_for(input_shape)
self.W_shape = (output_length, self.filter_length * input_dim, nb_filter)
self.W = self.init(self.W_shape, name='{}_W'.format(self.name))
self.W_shape = (output_length,
self.filter_length * input_dim,
nb_filter)
self.W = self.add_weight(self.W_shape,
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
if self.bias:
self.b = K.zeros((output_length, self.nb_filter), name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.b]
self.b = self.add_weight((output_length, self.nb_filter),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer,
constraint=self.b_constraint)
else:
self.trainable_weights = [self.W]
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
if self.b_constraint:
self.constraints[self.b] = self.b_constraint
self.b = None
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def get_output_shape_for(self, input_shape):
length = conv_output_length(input_shape[1],
@@ -254,7 +249,7 @@ class LocallyConnected2D(Layer):
`rows` and `cols` values might have changed due to padding.
'''
def __init__(self, nb_filter, nb_row, nb_col,
init='glorot_uniform', activation='linear', weights=None,
init='glorot_uniform', activation=None, weights=None,
border_mode='valid', subsample=(1, 1),
dim_ordering='default',
W_regularizer=None, b_regularizer=None, activity_regularizer=None,
@@ -263,8 +258,8 @@ class LocallyConnected2D(Layer):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
if border_mode != 'valid':
raise Exception('Invalid border mode for LocallyConnected2D '
'(only "valid" is supported):', border_mode)
raise ValueError('Invalid border mode for LocallyConnected2D '
'(only "valid" is supported):', border_mode)
self.nb_filter = nb_filter
self.nb_row = nb_row
self.nb_col = nb_col
@@ -273,7 +268,8 @@ class LocallyConnected2D(Layer):
self.border_mode = border_mode
self.subsample = tuple(subsample)
assert dim_ordering in {'tf', 'th'}, 'dim_ordering must be in {tf, th}'
if dim_ordering not in {'tf', 'th'}:
raise ValueError('`dim_ordering` must be in {tf, th}.')
self.dim_ordering = dim_ordering
self.W_regularizer = regularizers.get(W_regularizer)
@@ -297,39 +293,31 @@ class LocallyConnected2D(Layer):
_, output_row, output_col, nb_filter = output_shape
input_filter = input_shape[3]
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
self.output_row = output_row
self.output_col = output_col
self.W_shape = (output_row * output_col, self.nb_row * self.nb_col * input_filter, nb_filter)
self.W = self.init(self.W_shape, name='{}_W'.format(self.name))
self.W_shape = (output_row * output_col,
self.nb_row * self.nb_col * input_filter,
nb_filter)
self.W = self.add_weight(self.W_shape,
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer,
constraint=self.W_constraint)
if self.bias:
self.b = K.zeros((output_row, output_col, nb_filter), name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.b]
self.b = self.add_weight((output_row, output_col, nb_filter),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer,
constraint=self.b_constraint)
else:
self.trainable_weights = [self.W]
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.bias and self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.activity_regularizer:
self.activity_regularizer.set_layer(self)
self.regularizers.append(self.activity_regularizer)
self.constraints = {}
if self.W_constraint:
self.constraints[self.W] = self.W_constraint
if self.bias and self.b_constraint:
self.constraints[self.b] = self.b_constraint
self.b = None
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def get_output_shape_for(self, input_shape):
if self.dim_ordering == 'th':
@@ -339,7 +327,7 @@ class LocallyConnected2D(Layer):
rows = input_shape[1]
cols = input_shape[2]
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
rows = conv_output_length(rows, self.nb_row,
self.border_mode, self.subsample[0])
@@ -350,8 +338,6 @@ class LocallyConnected2D(Layer):
return (input_shape[0], self.nb_filter, rows, cols)
elif self.dim_ordering == 'tf':
return (input_shape[0], rows, cols, self.nb_filter)
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
def call(self, x, mask=None):
stride_row, stride_col = self.subsample
@@ -396,15 +382,13 @@ class LocallyConnected2D(Layer):
output = K.reshape(output, (self.output_row, self.output_col, -1, nb_filter))
output = K.permute_dimensions(output, (2, 0, 1, 3))
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
if self.bias:
if self.dim_ordering == 'th':
output += K.reshape(self.b, (1, nb_filter, self.output_row, self.output_col))
elif self.dim_ordering == 'tf':
output += K.reshape(self.b, (1, self.output_row, self.output_col, nb_filter))
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
output = self.activation(output)
return output
+39 -41
Ver Arquivo
@@ -1,5 +1,5 @@
from ..engine import Layer, InputSpec
from .. import initializations
from .. import initializations, regularizers
from .. import backend as K
@@ -10,6 +10,7 @@ class BatchNormalization(Layer):
# Arguments
epsilon: small float > 0. Fuzz parameter.
Theano expects epsilon >= 1e-5.
mode: integer, 0, 1 or 2.
- 0: feature-wise normalization.
Each feature map in the input will
@@ -44,6 +45,10 @@ 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`
@@ -54,10 +59,11 @@ class BatchNormalization(Layer):
Same shape as input.
# References
- [Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift](http://jmlr.org/proceedings/papers/v37/ioffe15.html)
- [Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift](http://jmlr.org/proceedings/papers/v37/ioffe15.pdf)
'''
def __init__(self, epsilon=1e-5, mode=0, axis=-1, momentum=0.99,
weights=None, beta_init='zero', gamma_init='one', **kwargs):
def __init__(self, epsilon=1e-3, mode=0, axis=-1, momentum=0.99,
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 +71,8 @@ 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
@@ -74,55 +82,43 @@ class BatchNormalization(Layer):
self.input_spec = [InputSpec(shape=input_shape)]
shape = (input_shape[self.axis],)
self.gamma = self.gamma_init(shape, name='{}_gamma'.format(self.name))
self.beta = self.beta_init(shape, name='{}_beta'.format(self.name))
self.trainable_weights = [self.gamma, self.beta]
self.running_mean = K.zeros(shape,
name='{}_running_mean'.format(self.name))
self.running_std = K.ones(shape,
name='{}_running_std'.format(self.name))
self.non_trainable_weights = [self.running_mean, self.running_std]
self.gamma = self.add_weight(shape,
initializer=self.gamma_init,
regularizer=self.gamma_regularizer,
name='{}_gamma'.format(self.name))
self.beta = self.add_weight(shape,
initializer=self.beta_init,
regularizer=self.beta_regularizer,
name='{}_beta'.format(self.name))
self.running_mean = self.add_weight(shape, initializer='zero',
name='{}_running_mean'.format(self.name),
trainable=False)
self.running_std = self.add_weight(shape, initializer='one',
name='{}_running_std'.format(self.name),
trainable=False)
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
self.called_with = None
def call(self, x, mask=None):
if self.mode == 0 or self.mode == 2:
assert self.built, 'Layer must be built before being called'
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
reduction_axes = list(range(len(input_shape)))
del reduction_axes[self.axis]
broadcast_shape = [1] * len(input_shape)
broadcast_shape[self.axis] = input_shape[self.axis]
if self.mode == 2:
x_normed, mean, std = K.normalize_batch_in_training(
x, self.gamma, self.beta, reduction_axes,
epsilon=self.epsilon)
else:
# mode 0
if self.called_with not in {None, x}:
raise Exception('You are attempting to share a '
'same `BatchNormalization` layer across '
'different data flows. '
'This is not possible. '
'You should use `mode=2` in '
'`BatchNormalization`, which has '
'a similar behavior but is shareable '
'(see docs for a description of '
'the behavior).')
self.called_with = x
x_normed, mean, std = K.normalize_batch_in_training(
x, self.gamma, self.beta, reduction_axes,
epsilon=self.epsilon)
x_normed, mean, std = K.normalize_batch_in_training(
x, self.gamma, self.beta, reduction_axes,
epsilon=self.epsilon)
self.updates = [K.moving_average_update(self.running_mean, mean, self.momentum),
K.moving_average_update(self.running_std, std, self.momentum)]
if self.mode == 0:
self.add_update([K.moving_average_update(self.running_mean, mean, self.momentum),
K.moving_average_update(self.running_std, std, self.momentum)], x)
if sorted(reduction_axes) == range(K.ndim(x))[:-1]:
x_normed_running = K.batch_normalization(
@@ -152,9 +148,11 @@ class BatchNormalization(Layer):
return x_normed
def get_config(self):
config = {"epsilon": self.epsilon,
"mode": self.mode,
"axis": self.axis,
"momentum": self.momentum}
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()))
+232 -30
Ver Arquivo
@@ -20,7 +20,8 @@ class _Pooling1D(Layer):
self.stride = stride
self.st = (self.stride, 1)
self.pool_size = (pool_length, 1)
assert border_mode in {'valid', 'same'}, 'border_mode must be in {valid, same}'
if border_mode not in {'valid', 'same'}:
raise ValueError('`border_mode` must be in {valid, same}.')
self.border_mode = border_mode
self.input_spec = [InputSpec(ndim=3)]
@@ -34,14 +35,12 @@ class _Pooling1D(Layer):
raise NotImplementedError
def call(self, x, mask=None):
x = K.expand_dims(x, -1) # add dummy last dimension
x = K.permute_dimensions(x, (0, 2, 1, 3))
x = K.expand_dims(x, 2) # add dummy last dimension
output = self._pooling_function(inputs=x, pool_size=self.pool_size,
strides=self.st,
border_mode=self.border_mode,
dim_ordering='th')
output = K.permute_dimensions(output, (0, 2, 1, 3))
return K.squeeze(output, 3) # remove dummy last dimension
dim_ordering='tf')
return K.squeeze(output, 2) # remove dummy last dimension
def get_config(self):
config = {'stride': self.stride,
@@ -66,7 +65,6 @@ class MaxPooling1D(_Pooling1D):
2 will halve the input.
If None, it will default to `pool_length`.
border_mode: 'valid' or 'same'.
Note: 'same' will only work with TensorFlow for the time being.
'''
def __init__(self, pool_length=2, stride=None,
@@ -89,7 +87,6 @@ class AveragePooling1D(_Pooling1D):
stride: integer, or None. Stride value.
If None, it will default to `pool_length`.
border_mode: 'valid' or 'same'.
Note: 'same' will only work with TensorFlow for the time being.
# Input shape
3D tensor with shape: `(samples, steps, features)`.
@@ -123,9 +120,11 @@ class _Pooling2D(Layer):
if strides is None:
strides = self.pool_size
self.strides = tuple(strides)
assert border_mode in {'valid', 'same'}, 'border_mode must be in {valid, same}'
if border_mode not in {'valid', 'same'}:
raise ValueError('`border_mode` must be in {valid, same}.')
self.border_mode = border_mode
assert dim_ordering in {'tf', 'th'}, 'dim_ordering must be in {tf, th}'
if dim_ordering not in {'tf', 'th'}:
raise ValueError('`dim_ordering` must be in {tf, th}.')
self.dim_ordering = dim_ordering
self.input_spec = [InputSpec(ndim=4)]
@@ -137,7 +136,7 @@ class _Pooling2D(Layer):
rows = input_shape[1]
cols = input_shape[2]
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
rows = conv_output_length(rows, self.pool_size[0],
self.border_mode, self.strides[0])
@@ -148,15 +147,14 @@ class _Pooling2D(Layer):
return (input_shape[0], input_shape[1], rows, cols)
elif self.dim_ordering == 'tf':
return (input_shape[0], rows, cols, input_shape[3])
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
def _pooling_function(self, inputs, pool_size, strides,
border_mode, dim_ordering):
raise NotImplementedError
def call(self, x, mask=None):
output = self._pooling_function(inputs=x, pool_size=self.pool_size,
output = self._pooling_function(inputs=x,
pool_size=self.pool_size,
strides=self.strides,
border_mode=self.border_mode,
dim_ordering=self.dim_ordering)
@@ -181,12 +179,11 @@ class MaxPooling2D(_Pooling2D):
strides: tuple of 2 integers, or None. Strides values.
If None, it will default to `pool_size`.
border_mode: 'valid' or 'same'.
Note: 'same' will only work with TensorFlow for the time being.
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".
If you never set it, then it will be "tf".
# Input shape
4D tensor with shape:
@@ -209,7 +206,8 @@ class MaxPooling2D(_Pooling2D):
def _pooling_function(self, inputs, pool_size, strides,
border_mode, dim_ordering):
output = K.pool2d(inputs, pool_size, strides,
border_mode, dim_ordering, pool_mode='max')
border_mode, dim_ordering,
pool_mode='max')
return output
@@ -223,12 +221,11 @@ class AveragePooling2D(_Pooling2D):
strides: tuple of 2 integers, or None. Strides values.
If None, it will default to `pool_size`.
border_mode: 'valid' or 'same'.
Note: 'same' will only work with TensorFlow for the time being.
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".
If you never set it, then it will be "tf".
# Input shape
4D tensor with shape:
@@ -268,9 +265,11 @@ class _Pooling3D(Layer):
if strides is None:
strides = self.pool_size
self.strides = tuple(strides)
assert border_mode in {'valid', 'same'}, 'border_mode must be in {valid, same}'
if border_mode not in {'valid', 'same'}:
raise ValueError('`border_mode` must be in {valid, same}.')
self.border_mode = border_mode
assert dim_ordering in {'tf', 'th'}, 'dim_ordering must be in {tf, th}'
if dim_ordering not in {'tf', 'th'}:
raise ValueError('`dim_ordering` must be in {tf, th}.')
self.dim_ordering = dim_ordering
self.input_spec = [InputSpec(ndim=5)]
@@ -284,7 +283,7 @@ class _Pooling3D(Layer):
len_dim2 = input_shape[2]
len_dim3 = input_shape[3]
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
raise ValueError('Invalid dim_ordering:', self.dim_ordering)
len_dim1 = conv_output_length(len_dim1, self.pool_size[0],
self.border_mode, self.strides[0])
@@ -292,13 +291,14 @@ class _Pooling3D(Layer):
self.border_mode, self.strides[1])
len_dim3 = conv_output_length(len_dim3, self.pool_size[2],
self.border_mode, self.strides[2])
if self.dim_ordering == 'th':
return (input_shape[0], input_shape[1], len_dim1, len_dim2, len_dim3)
return (input_shape[0],
input_shape[1],
len_dim1, len_dim2, len_dim3)
elif self.dim_ordering == 'tf':
return (input_shape[0], len_dim1, len_dim2, len_dim3, input_shape[4])
else:
raise Exception('Invalid dim_ordering: ' + self.dim_ordering)
return (input_shape[0],
len_dim1, len_dim2, len_dim3,
input_shape[4])
def _pooling_function(self, inputs, pool_size, strides,
border_mode, dim_ordering):
@@ -333,7 +333,7 @@ class MaxPooling3D(_Pooling3D):
(the depth) is at index 1, in 'tf' mode is it at index 4.
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".
If you never set it, then it will be "tf".
# Input shape
5D tensor with shape:
@@ -373,7 +373,7 @@ class AveragePooling3D(_Pooling3D):
(the depth) is at index 1, in 'tf' mode is it at index 4.
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".
If you never set it, then it will be "tf".
# Input shape
5D tensor with shape:
@@ -396,5 +396,207 @@ class AveragePooling3D(_Pooling3D):
def _pooling_function(self, inputs, pool_size, strides,
border_mode, dim_ordering):
output = K.pool3d(inputs, pool_size, strides,
border_mode, dim_ordering, pool_mode='avg')
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()
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 "tf".
# 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 "tf".
# 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])
class _GlobalPooling3D(Layer):
def __init__(self, dim_ordering='default', **kwargs):
super(_GlobalPooling3D, self).__init__(**kwargs)
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
self.dim_ordering = dim_ordering
self.input_spec = [InputSpec(ndim=5)]
def get_output_shape_for(self, input_shape):
if self.dim_ordering == 'tf':
return (input_shape[0], input_shape[4])
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(_GlobalPooling3D, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class GlobalAveragePooling3D(_GlobalPooling3D):
'''Global Average pooling operation for 3D 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 4.
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 "tf".
# Input shape
5D tensor with shape:
`(samples, channels, len_pool_dim1, len_pool_dim2, len_pool_dim3)` if dim_ordering='th'
or 5D tensor with shape:
`(samples, len_pool_dim1, len_pool_dim2, len_pool_dim3, 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, 3])
else:
return K.mean(x, axis=[2, 3, 4])
class GlobalMaxPooling3D(_GlobalPooling3D):
'''Global Max pooling operation for 3D 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 4.
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 "tf".
# Input shape
5D tensor with shape:
`(samples, channels, len_pool_dim1, len_pool_dim2, len_pool_dim3)` if dim_ordering='th'
or 5D tensor with shape:
`(samples, len_pool_dim1, len_pool_dim2, len_pool_dim3, 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, 3])
else:
return K.max(x, axis=[2, 3, 4])
+182 -137
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.stack([-1, timesteps, output_dim]))
x.set_shape([None, None, output_dim])
else:
x = K.reshape(x, (-1, timesteps, output_dim))
return x
@@ -196,7 +198,19 @@ class Recurrent(Layer):
# input shape: (nb_samples, time (padded with zeros), input_dim)
# note that the .build() method of subclasses MUST define
# self.input_spec with a complete input shape.
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
if self.unroll and input_shape[1] is None:
raise ValueError('Cannot unroll a RNN if the '
'time dimension is undefined. \n'
'- If using a Sequential model, '
'specify the time dimension by passing '
'an `input_shape` or `batch_input_shape` '
'argument to your first layer. If your '
'first layer is an Embedding, you can '
'also use the `input_length` argument.\n'
'- If using the functional API, specify '
'the time dimension by passing a `shape` '
'or `batch_shape` argument to your Input layer.')
if self.stateful:
initial_states = self.states
else:
@@ -212,9 +226,10 @@ class Recurrent(Layer):
unroll=self.unroll,
input_length=input_shape[1])
if self.stateful:
self.updates = []
updates = []
for i in range(len(states)):
self.updates.append((self.states[i], states[i]))
updates.append((self.states[i], states[i]))
self.add_update(updates, x)
if self.return_sequences:
return outputs
@@ -227,7 +242,7 @@ class Recurrent(Layer):
'stateful': self.stateful,
'unroll': self.unroll,
'consume_less': self.consume_less}
if self.stateful:
if self.stateful and self.input_spec[0].shape:
config['batch_input_shape'] = self.input_spec[0].shape
else:
config['input_dim'] = self.input_dim
@@ -273,7 +288,8 @@ class SimpleRNN(Recurrent):
self.W_regularizer = regularizers.get(W_regularizer)
self.U_regularizer = regularizers.get(U_regularizer)
self.b_regularizer = regularizers.get(b_regularizer)
self.dropout_W, self.dropout_U = dropout_W, dropout_U
self.dropout_W = dropout_W
self.dropout_U = dropout_U
if self.dropout_W or self.dropout_U:
self.uses_learning_phase = True
@@ -289,35 +305,38 @@ class SimpleRNN(Recurrent):
input_dim = input_shape[2]
self.input_dim = input_dim
self.W = self.init((input_dim, self.output_dim),
name='{}_W'.format(self.name))
self.U = self.inner_init((self.output_dim, self.output_dim),
name='{}_U'.format(self.name))
self.b = K.zeros((self.output_dim,), name='{}_b'.format(self.name))
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.U_regularizer:
self.U_regularizer.set_param(self.U)
self.regularizers.append(self.U_regularizer)
if self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
self.trainable_weights = [self.W, self.U, self.b]
self.W = self.add_weight((input_dim, self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer)
self.U = self.add_weight((self.output_dim, self.output_dim),
initializer=self.inner_init,
name='{}_U'.format(self.name),
regularizer=self.U_regularizer)
self.b = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer)
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def reset_states(self):
assert self.stateful, 'Layer must be stateful.'
input_shape = self.input_spec[0].shape
if not input_shape[0]:
raise Exception('If a RNN is stateful, a complete ' +
'input_shape must be provided (including batch size).')
raise ValueError('If a RNN is stateful, it needs to know '
'its batch size. Specify the batch size '
'of your input tensors: \n'
'- If using a Sequential model, '
'specify the batch size by passing '
'a `batch_input_shape` '
'argument to your first layer.\n'
'- If using the functional API, specify '
'the time dimension by passing a '
'`batch_shape` argument to your Input layer.')
if hasattr(self, 'states'):
K.set_value(self.states[0],
np.zeros((input_shape[0], self.output_dim)))
@@ -326,7 +345,7 @@ class SimpleRNN(Recurrent):
def preprocess_input(self, x):
if self.consume_less == 'cpu':
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
input_dim = input_shape[2]
timesteps = input_shape[1]
return time_distributed_dense(x, self.W, self.b, self.dropout_W,
@@ -358,10 +377,10 @@ class SimpleRNN(Recurrent):
else:
constants.append(K.cast_to_floatx(1.))
if self.consume_less == 'cpu' and 0 < self.dropout_W < 1:
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
input_dim = input_shape[-1]
ones = K.ones_like(K.reshape(x[:, 0, 0], (-1, 1)))
ones = K.tile(ones, (1, input_dim))
ones = K.tile(ones, (1, int(input_dim)))
B_W = K.in_train_phase(K.dropout(ones, self.dropout_W), ones)
constants.append(B_W)
else:
@@ -405,7 +424,7 @@ class GRU(Recurrent):
dropout_U: float between 0 and 1. Fraction of the input units to drop for recurrent connections.
# References
- [On the Properties of Neural Machine Translation: EncoderDecoder Approaches](http://www.aclweb.org/anthology/W14-4012)
- [On the Properties of Neural Machine Translation: Encoder-Decoder Approaches](http://www.aclweb.org/anthology/W14-4012)
- [Empirical Evaluation of Gated Recurrent Neural Networks on Sequence Modeling](http://arxiv.org/pdf/1412.3555v1.pdf)
- [A Theoretically Grounded Application of Dropout in Recurrent Neural Networks](http://arxiv.org/abs/1512.05287)
'''
@@ -422,7 +441,8 @@ class GRU(Recurrent):
self.W_regularizer = regularizers.get(W_regularizer)
self.U_regularizer = regularizers.get(U_regularizer)
self.b_regularizer = regularizers.get(b_regularizer)
self.dropout_W, self.dropout_U = dropout_W, dropout_U
self.dropout_W = dropout_W
self.dropout_U = dropout_U
if self.dropout_W or self.dropout_U:
self.uses_learning_phase = True
@@ -439,67 +459,70 @@ class GRU(Recurrent):
self.states = [None]
if self.consume_less == 'gpu':
self.W = self.init((self.input_dim, 3 * self.output_dim),
name='{}_W'.format(self.name))
self.U = self.inner_init((self.output_dim, 3 * self.output_dim),
name='{}_U'.format(self.name))
self.b = K.variable(np.hstack((np.zeros(self.output_dim),
np.zeros(self.output_dim),
np.zeros(self.output_dim))),
name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.U, self.b]
self.W = self.add_weight((self.input_dim, 3 * self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer)
self.U = self.add_weight((self.output_dim, 3 * self.output_dim),
initializer=self.inner_init,
name='{}_U'.format(self.name),
regularizer=self.U_regularizer)
self.b = self.add_weight((self.output_dim * 3,),
initializer='zero',
name='{}_b'.format(self.name),
regularizer=self.b_regularizer)
else:
self.W_z = self.init((self.input_dim, self.output_dim),
name='{}_W_z'.format(self.name))
self.U_z = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_z'.format(self.name))
self.b_z = K.zeros((self.output_dim,), name='{}_b_z'.format(self.name))
self.W_r = self.init((self.input_dim, self.output_dim),
name='{}_W_r'.format(self.name))
self.U_r = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_r'.format(self.name))
self.b_r = K.zeros((self.output_dim,), name='{}_b_r'.format(self.name))
self.W_h = self.init((self.input_dim, self.output_dim),
name='{}_W_h'.format(self.name))
self.U_h = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_h'.format(self.name))
self.b_h = K.zeros((self.output_dim,), name='{}_b_h'.format(self.name))
self.trainable_weights = [self.W_z, self.U_z, self.b_z,
self.W_r, self.U_r, self.b_r,
self.W_h, self.U_h, self.b_h]
self.W_z = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_z'.format(self.name),
regularizer=self.W_regularizer)
self.U_z = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_z'.format(self.name),
regularizer=self.W_regularizer)
self.b_z = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b_z'.format(self.name),
regularizer=self.b_regularizer)
self.W_r = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_r'.format(self.name),
regularizer=self.W_regularizer)
self.U_r = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_r'.format(self.name),
regularizer=self.W_regularizer)
self.b_r = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b_r'.format(self.name),
regularizer=self.b_regularizer)
self.W_h = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_h'.format(self.name),
regularizer=self.W_regularizer)
self.U_h = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_h'.format(self.name),
regularizer=self.W_regularizer)
self.b_h = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b_h'.format(self.name),
regularizer=self.b_regularizer)
self.W = K.concatenate([self.W_z, self.W_r, self.W_h])
self.U = K.concatenate([self.U_z, self.U_r, self.U_h])
self.b = K.concatenate([self.b_z, self.b_r, self.b_h])
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.U_regularizer:
self.U_regularizer.set_param(self.U)
self.regularizers.append(self.U_regularizer)
if self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def reset_states(self):
assert self.stateful, 'Layer must be stateful.'
input_shape = self.input_spec[0].shape
if not input_shape[0]:
raise Exception('If a RNN is stateful, a complete ' +
'input_shape must be provided (including batch size).')
raise ValueError('If a RNN is stateful, a complete ' +
'input_shape must be provided (including batch size).')
if hasattr(self, 'states'):
K.set_value(self.states[0],
np.zeros((input_shape[0], self.output_dim)))
@@ -508,7 +531,7 @@ class GRU(Recurrent):
def preprocess_input(self, x):
if self.consume_less == 'cpu':
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
input_dim = input_shape[2]
timesteps = input_shape[1]
@@ -553,7 +576,7 @@ class GRU(Recurrent):
x_r = K.dot(x * B_W[1], self.W_r) + self.b_r
x_h = K.dot(x * B_W[2], self.W_h) + self.b_h
else:
raise Exception('Unknown `consume_less` mode.')
raise ValueError('Unknown `consume_less` mode.')
z = self.inner_activation(x_z + K.dot(h_tm1 * B_U[0], self.U_z))
r = self.inner_activation(x_r + K.dot(h_tm1 * B_U[1], self.U_r))
@@ -572,10 +595,10 @@ class GRU(Recurrent):
constants.append([K.cast_to_floatx(1.) for _ in range(3)])
if 0 < self.dropout_W < 1:
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
input_dim = input_shape[-1]
ones = K.ones_like(K.reshape(x[:, 0, 0], (-1, 1)))
ones = K.tile(ones, (1, input_dim))
ones = K.tile(ones, (1, int(input_dim)))
B_W = [K.in_train_phase(K.dropout(ones, self.dropout_W), ones) for _ in range(3)]
constants.append(B_W)
else:
@@ -628,7 +651,7 @@ class LSTM(Recurrent):
# References
- [Long short-term memory](http://deeplearning.cs.cmu.edu/pdfs/Hochreiter97_lstm.pdf) (original 1997 paper)
- [Learning to forget: Continual prediction with LSTM](http://www.mitpressjournals.org/doi/pdf/10.1162/089976600300015015)
- [Supervised sequence labelling with recurrent neural networks](http://www.cs.toronto.edu/~graves/preprint.pdf)
- [Supervised sequence labeling with recurrent neural networks](http://www.cs.toronto.edu/~graves/preprint.pdf)
- [A Theoretically Grounded Application of Dropout in Recurrent Neural Networks](http://arxiv.org/abs/1512.05287)
'''
def __init__(self, output_dim,
@@ -646,7 +669,8 @@ class LSTM(Recurrent):
self.W_regularizer = regularizers.get(W_regularizer)
self.U_regularizer = regularizers.get(U_regularizer)
self.b_regularizer = regularizers.get(b_regularizer)
self.dropout_W, self.dropout_U = dropout_W, dropout_U
self.dropout_W = dropout_W
self.dropout_U = dropout_U
if self.dropout_W or self.dropout_U:
self.uses_learning_phase = True
@@ -663,73 +687,94 @@ class LSTM(Recurrent):
self.states = [None, None]
if self.consume_less == 'gpu':
self.W = self.init((self.input_dim, 4 * self.output_dim),
name='{}_W'.format(self.name))
self.U = self.inner_init((self.output_dim, 4 * self.output_dim),
name='{}_U'.format(self.name))
self.W = self.add_weight((self.input_dim, 4 * self.output_dim),
initializer=self.init,
name='{}_W'.format(self.name),
regularizer=self.W_regularizer)
self.U = self.add_weight((self.output_dim, 4 * self.output_dim),
initializer=self.inner_init,
name='{}_U'.format(self.name),
regularizer=self.U_regularizer)
self.b = K.variable(np.hstack((np.zeros(self.output_dim),
K.get_value(self.forget_bias_init((self.output_dim,))),
np.zeros(self.output_dim),
np.zeros(self.output_dim))),
name='{}_b'.format(self.name))
self.trainable_weights = [self.W, self.U, self.b]
def b_reg(shape, name=None):
return K.variable(np.hstack((np.zeros(self.output_dim),
K.get_value(self.forget_bias_init((self.output_dim,))),
np.zeros(self.output_dim),
np.zeros(self.output_dim))),
name='{}_b'.format(self.name))
self.b = self.add_weight((self.output_dim * 4,),
initializer=b_reg,
name='{}_b'.format(self.name),
regularizer=self.b_regularizer)
else:
self.W_i = self.init((self.input_dim, self.output_dim),
name='{}_W_i'.format(self.name))
self.U_i = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_i'.format(self.name))
self.b_i = K.zeros((self.output_dim,), name='{}_b_i'.format(self.name))
self.W_f = self.init((self.input_dim, self.output_dim),
name='{}_W_f'.format(self.name))
self.U_f = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_f'.format(self.name))
self.b_f = self.forget_bias_init((self.output_dim,),
name='{}_b_f'.format(self.name))
self.W_c = self.init((self.input_dim, self.output_dim),
name='{}_W_c'.format(self.name))
self.U_c = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_c'.format(self.name))
self.b_c = K.zeros((self.output_dim,), name='{}_b_c'.format(self.name))
self.W_o = self.init((self.input_dim, self.output_dim),
name='{}_W_o'.format(self.name))
self.U_o = self.inner_init((self.output_dim, self.output_dim),
name='{}_U_o'.format(self.name))
self.b_o = K.zeros((self.output_dim,), name='{}_b_o'.format(self.name))
self.W_i = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_i'.format(self.name),
regularizer=self.W_regularizer)
self.U_i = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_i'.format(self.name),
regularizer=self.W_regularizer)
self.b_i = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b_i'.format(self.name),
regularizer=self.b_regularizer)
self.W_f = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_f'.format(self.name),
regularizer=self.W_regularizer)
self.U_f = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_f'.format(self.name),
regularizer=self.W_regularizer)
self.b_f = self.add_weight((self.output_dim,),
initializer=self.forget_bias_init,
name='{}_b_f'.format(self.name),
regularizer=self.b_regularizer)
self.W_c = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_c'.format(self.name),
regularizer=self.W_regularizer)
self.U_c = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_c'.format(self.name),
regularizer=self.W_regularizer)
self.b_c = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b_c'.format(self.name),
regularizer=self.b_regularizer)
self.W_o = self.add_weight((self.input_dim, self.output_dim),
initializer=self.init,
name='{}_W_o'.format(self.name),
regularizer=self.W_regularizer)
self.U_o = self.add_weight((self.output_dim, self.output_dim),
initializer=self.init,
name='{}_U_o'.format(self.name),
regularizer=self.W_regularizer)
self.b_o = self.add_weight((self.output_dim,),
initializer='zero',
name='{}_b_o'.format(self.name),
regularizer=self.b_regularizer)
self.trainable_weights = [self.W_i, self.U_i, self.b_i,
self.W_c, self.U_c, self.b_c,
self.W_f, self.U_f, self.b_f,
self.W_o, self.U_o, self.b_o]
self.W = K.concatenate([self.W_i, self.W_f, self.W_c, self.W_o])
self.U = K.concatenate([self.U_i, self.U_f, self.U_c, self.U_o])
self.b = K.concatenate([self.b_i, self.b_f, self.b_c, self.b_o])
self.regularizers = []
if self.W_regularizer:
self.W_regularizer.set_param(self.W)
self.regularizers.append(self.W_regularizer)
if self.U_regularizer:
self.U_regularizer.set_param(self.U)
self.regularizers.append(self.U_regularizer)
if self.b_regularizer:
self.b_regularizer.set_param(self.b)
self.regularizers.append(self.b_regularizer)
if self.initial_weights is not None:
self.set_weights(self.initial_weights)
del self.initial_weights
self.built = True
def reset_states(self):
assert self.stateful, 'Layer must be stateful.'
input_shape = self.input_spec[0].shape
if not input_shape[0]:
raise Exception('If a RNN is stateful, a complete ' +
'input_shape must be provided (including batch size).')
raise ValueError('If a RNN is stateful, a complete ' +
'input_shape must be provided (including batch size).')
if hasattr(self, 'states'):
K.set_value(self.states[0],
np.zeros((input_shape[0], self.output_dim)))
@@ -745,7 +790,7 @@ class LSTM(Recurrent):
dropout = self.dropout_W
else:
dropout = 0
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
input_dim = input_shape[2]
timesteps = input_shape[1]
@@ -791,7 +836,7 @@ class LSTM(Recurrent):
x_c = K.dot(x * B_W[2], self.W_c) + self.b_c
x_o = K.dot(x * B_W[3], self.W_o) + self.b_o
else:
raise Exception('Unknown `consume_less` mode.')
raise ValueError('Unknown `consume_less` mode.')
i = self.inner_activation(x_i + K.dot(h_tm1 * B_U[0], self.U_i))
f = self.inner_activation(x_f + K.dot(h_tm1 * B_U[1], self.U_f))
@@ -812,10 +857,10 @@ class LSTM(Recurrent):
constants.append([K.cast_to_floatx(1.) for _ in range(4)])
if 0 < self.dropout_W < 1:
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(x)
input_dim = input_shape[-1]
ones = K.ones_like(K.reshape(x[:, 0, 0], (-1, 1)))
ones = K.tile(ones, (1, input_dim))
ones = K.tile(ones, (1, int(input_dim)))
B_W = [K.in_train_phase(K.dropout(ones, self.dropout_W), ones) for _ in range(4)]
constants.append(B_W)
else:
+35 -27
Ver Arquivo
@@ -17,9 +17,16 @@ class Wrapper(Layer):
self.trainable_weights = getattr(self.layer, 'trainable_weights', [])
self.non_trainable_weights = getattr(self.layer, 'non_trainable_weights', [])
self.updates = getattr(self.layer, 'updates', [])
self.regularizers = getattr(self.layer, 'regularizers', [])
self.losses = getattr(self.layer, 'losses', [])
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)
@@ -110,15 +106,17 @@ class TimeDistributed(Wrapper):
return (child_output_shape[0], timesteps) + child_output_shape[1:]
def call(self, X, mask=None):
input_shape = self.input_spec[0].shape
input_shape = K.int_shape(X)
if input_shape[0]:
# batch size matters, use rnn-based implementation
def step(x, states):
output = self.layer.call(x)
return output, []
last_output, outputs, states = K.rnn(step, X,
initial_states=[])
_, outputs, _ = K.rnn(step, X,
initial_states=[],
input_length=input_shape[1],
unroll=False)
y = outputs
else:
# no batch size specified, therefore the layer will be able
@@ -127,29 +125,39 @@ class TimeDistributed(Wrapper):
input_length = input_shape[1]
if not input_length:
input_length = K.shape(X)[1]
X = K.reshape(X, (-1, ) + input_shape[2:]) # (nb_samples * timesteps, ...)
X = K.reshape(X, (-1,) + input_shape[2:]) # (nb_samples * timesteps, ...)
y = self.layer.call(X) # (nb_samples * timesteps, ...)
# (nb_samples, timesteps, ...)
output_shape = self.get_output_shape_for(input_shape)
y = K.reshape(y, (-1, input_length) + output_shape[2:])
# Apply activity regularizer if any:
if hasattr(self.layer, 'activity_regularizer') and self.layer.activity_regularizer is not None:
regularization_loss = self.layer.activity_regularizer(y)
self.add_loss(regularization_loss, X)
return y
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):
@@ -243,9 +251,9 @@ class Bidirectional(Wrapper):
return []
@property
def regularizers(self):
if hasattr(self.forward_layer, 'regularizers'):
return self.forward_layer.regularizers + self.backward_layer.regularizers
def losses(self):
if hasattr(self.forward_layer, 'losses'):
return self.forward_layer.losses + self.backward_layer.losses
return []
@property
Ver Arquivo
-775
Ver Arquivo
@@ -1,775 +0,0 @@
from collections import OrderedDict
import warnings
import copy
from .. import backend as K
from ..layers import InputLayer, Layer, Merge
from ..engine.training import Model
class Graph(Model):
'''Arbitrary connection graph.
THIS IS A LEGACY MODEL AND SHOULD NOT BE USED
except for backwards compatibility support.
For multi-inputs/multi-outputs models, or
models using shared layers, use the functional API instead.
'''
def __init__(self, name=None):
# model attributes
self.inbound_nodes = []
self.outbound_nodes = []
self.built = False
self.supports_masking = False
# legacy attributes (we prefix them with _graph_)
self._graph_namespace = set() # strings
self._graph_nodes = OrderedDict() # layer-like
self._graph_inputs = OrderedDict() # layer-like
self._graph_outputs = OrderedDict() # layer-like
self._graph_input_config = [] # dicts
self._graph_output_config = [] # dicts
self._graph_node_config = [] # dicts
self._graph_shared_nodes_names = []
if not name:
prefix = 'graph_'
name = prefix + str(K.get_uid(prefix))
self.name = name
def __call__(self, x, mask=None):
self.build()
return super(Graph, self).__call__(x, mask)
def build(self, input_shape=None):
# this will crash if the input/output layers have multiple nodes
# no plans to support that case since Graph is deprecated
input_tensors = [layer.output for layer in self._graph_inputs.values()]
output_tensors = [layer.output for layer in self._graph_outputs.values()]
# actually create the model
super(Graph, self).__init__(input_tensors,
output_tensors,
name=self.name)
self.built = True
def compile(self, optimizer, loss,
metrics=[],
sample_weight_modes=None,
loss_weights=None,
**kwargs):
'''Configures the learning process.
# Arguments
optimizer: str (name of optimizer) or optimizer object.
See [optimizers](optimizers.md).
loss: dictionary mapping the name(s) of the output(s) to
a loss function (string name of objective function or
objective function. See [objectives](objectives.md)).
metrics: list of str (name of metrics) or
list of metrics functions. See [metrics](metrics.md).
sample_weight_modes: optional dictionary mapping certain
output names to a sample weight mode ("temporal" and None
are the only supported modes). If you need to do
timestep-wise loss weighting on one of your graph outputs,
you will need to set the sample weight mode for this output
to "temporal".
loss_weights: dictionary you can pass to specify a weight
coefficient for each loss function (in a multi-output model).
If no loss weight is specified for an output,
the weight for this output's loss will be considered to be 1.
kwargs: for Theano backend, these are passed into K.function.
Ignored for Tensorflow backend.
'''
# create the underlying Model
if not self.built:
self.build()
super(Graph, self).compile(optimizer, loss,
metrics=metrics,
sample_weight_mode=sample_weight_modes,
loss_weights=loss_weights,
**kwargs)
def add_input(self, name, input_shape=None,
batch_input_shape=None, dtype='float'):
'''Adds an input to the graph.
# Arguments:
name: string. The name of the new input.
Must be unique in the graph.
input_shape: a tuple of integers,
the expected shape of the input samples.
Does not include the batch size.
batch_input_shape: a tuple of integers,
the expected shape of the whole input batch,
including the batch size.
dtype: 'float', or 'int'.
'''
if name in self._graph_namespace:
raise Exception('Duplicate node identifier: ' + name)
self._graph_namespace.add(name)
self.built = False
if dtype[:3] == 'int':
dtype = 'int32'
elif dtype[:5] == 'float':
dtype = K.floatx()
else:
raise Exception('Uknown dtype (should be "int" or "float"): ' +
str(dtype))
# create input layer
input_layer = InputLayer(input_shape=input_shape,
batch_input_shape=batch_input_shape,
name=name, input_dtype=dtype)
self._graph_inputs[name] = input_layer
# append input config to self._graph_input_config
config = {'name': name, 'dtype': dtype}
if batch_input_shape:
config['batch_input_shape'] = batch_input_shape
else:
config['input_shape'] = input_shape
self._graph_input_config.append(config)
def add_node(self, layer, name, input=None, inputs=[],
merge_mode='concat', concat_axis=-1, dot_axes=-1,
create_output=False):
'''Adds a node in the graph. It can be connected to multiple
inputs, which will first be merged into one tensor
according to the mode specified.
# Arguments
layer: the layer at the node.
name: name for the node.
input: when connecting the layer to a single input,
this is the name of the incoming node.
inputs: when connecting the layer to multiple inputs,
this is a list of names of incoming nodes.
merge_mode: one of {concat, sum, dot, ave, mul}
concat_axis: when `merge_mode=='concat'`, this is the
input concatenation axis.
dot_axes: when `merge_mode='dot'`,
this is the contraction axes specification;
see the `Merge` layer for details.
create_output: boolean. Set this to `True` if you want the output
of your node to be an output of the graph.
'''
if name in self._graph_namespace:
raise Exception('Duplicate node identifier: ' + name)
self._graph_namespace.add(name)
layer.name = name
self.built = False
if input:
if input not in self._graph_namespace:
raise Exception('Unknown node/input identifier: ' + input)
if input in self._graph_nodes:
layer.add_inbound_node(self._graph_nodes[input])
elif input in self._graph_inputs:
layer.add_inbound_node(self._graph_inputs[input])
if inputs:
to_merge = []
for n in inputs:
if n in self._graph_nodes:
to_merge.append(self._graph_nodes[n])
elif n in self._graph_inputs:
to_merge.append(self._graph_inputs[n])
else:
raise Exception('Unknown identifier: ' + n)
merge = Merge(to_merge, mode=merge_mode,
concat_axis=concat_axis, dot_axes=dot_axes,
name='merge_inputs_for_' + name)
layer.add_inbound_node(merge)
self._graph_nodes[name] = layer
self._graph_node_config.append({'name': name,
'input': input,
'inputs': inputs,
'merge_mode': merge_mode,
'concat_axis': concat_axis,
'dot_axes': dot_axes,
'create_output': create_output})
if create_output:
self.add_output(name, input=name)
def add_shared_node(self, layer, name, inputs=[], merge_mode=None,
concat_axis=-1, dot_axes=-1, outputs=[],
create_output=False):
'''Used to share a same layer across multiple nodes.
Supposed, for instance, that you want to apply one same `Dense` layer
after two different nodes ('node_a' and 'node_b').
You can then add the dense layer as a shared node by calling:
```python
model.add_shared_node(my_dense, name='shared_dense', inputs=['node_a', 'node_b'], ...)
```
If you want access to the output of dense(node_a) and dense(node_b) separately,
you can add these outputs to the Graph by passing an `outputs` argument:
```python
model.add_shared_node(my_dense, name='shared_dense', inputs=['node_a', 'node_b'],
outputs=['dense_output_a', 'dense_outputs_b'])
```
Otherwise you can merge these different outputs via `merge_mode`.
In that case you can access the merged output
under the identifier `name`.
# Arguments
layer: The layer to be shared across multiple inputs
name: Name of the shared node
inputs: List of names of input nodes
merge_mode: Same meaning as `merge_mode` argument of `add_node()`
concat_axis: Same meaning as `concat_axis` argument of `add_node()`
dot_axes: Same meaning as `dot_axes` argument of `add_node()`
outputs: Used when `merge_mode=None`. Names for the output nodes.
create_output: Same meaning as `create_output` argument of `add_node()`.
'''
if name in self._graph_namespace:
raise Exception('Duplicate node identifier: ' + name)
self._graph_namespace.add(name)
self.built = False
for o in outputs:
if o in self._graph_namespace:
raise Exception('Duplicate node identifier: ' + o)
if merge_mode:
if merge_mode not in {'sum', 'ave', 'mul', 'dot', 'cos', 'concat'}:
raise Exception('Invalid merge mode:', merge_mode)
input_layers = []
for i in range(len(inputs)):
input = inputs[i]
if input in self._graph_nodes:
n = self._graph_nodes[input]
input_layers.append(n)
elif input in self._graph_inputs:
n = self._graph_inputs[input]
input_layers.append(n)
else:
raise Exception('Unknown identifier: ' + input)
created_node_indices = []
for input_layer in input_layers:
created_node_indices.append(len(layer.inbound_nodes))
layer.add_inbound_node(input_layer)
if merge_mode:
layer.name = 'input_for_' + name
# collect all output nodes of layer and merge them into a single output
merge = Merge([layer for _ in range(len(inputs))],
mode=merge_mode,
concat_axis=concat_axis, dot_axes=dot_axes,
node_indices=created_node_indices,
name=name)
self._graph_nodes[name] = merge
if create_output:
self.add_output(name, input=name)
else:
layer.name = name
# create one new layer per output node of layer,
# and add them to the Graph with their own identifiers
if len(outputs) != len(inputs):
raise Exception('When using merge_mode=None, '
'you should provide a list of '
'output names (`output` argument) '
'the same size as `input`.')
for i in range(len(outputs)):
output_layer_name = outputs[i]
output_layer = Layer(name=output_layer_name)
output_layer.add_inbound_node(layer, created_node_indices[i])
self._graph_namespace.add(output_layer_name)
self._graph_nodes[output_layer_name] = output_layer
if create_output:
self.add_output(output_layer_name, input=output_layer_name)
self._graph_node_config.append({'name': name,
'layer': {
'config': layer.get_config(),
'class_name': layer.__class__.__name__,
},
'inputs': inputs,
'merge_mode': merge_mode,
'concat_axis': concat_axis,
'dot_axes': dot_axes,
'outputs': outputs,
'create_output': create_output if merge_mode else False})
self._graph_shared_nodes_names.append(name)
def add_output(self, name, input=None, inputs=[],
merge_mode='concat', concat_axis=-1, dot_axes=-1):
'''Adds an output to the graph.
This output can merge several node outputs into a single output.
# Arguments
name: name of the output.
input: when connecting the layer to a single input,
this is the name of the incoming node.
inputs: when connecting the layer to multiple inputs,
this is a list of names of incoming nodes.
merge_mode: one of {concat, sum, dot, ave, mul}
concat_axis: when `merge_mode=='concat'`, this is the
input concatenation axis.
dot_axes: when `merge_mode='dot'`,
this is the contraction axes specification;
see the `Merge layer for details.
'''
if name not in self._graph_namespace:
self._graph_namespace.add(name)
if name in self._graph_outputs:
raise Exception('Duplicate output identifier:', name)
self.built = False
if input:
if input in self._graph_nodes:
layer = self._graph_nodes[input]
elif input in self._graph_inputs:
layer = self._graph_inputs[input]
else:
raise Exception('Unknown node/input identifier: ' + input)
if layer.name == name:
self._graph_outputs[name] = layer
else:
layer.name = name
self._graph_outputs[name] = layer
if inputs:
to_merge = []
for n in inputs:
if n not in self._graph_nodes:
raise Exception('Unknown identifier: ' + n)
to_merge.append(self._graph_nodes[n])
merge = Merge(to_merge, mode=merge_mode,
concat_axis=concat_axis, dot_axes=dot_axes,
name=name)
self._graph_outputs[name] = merge
self._graph_output_config.append({'name': name,
'input': input,
'inputs': inputs,
'merge_mode': merge_mode,
'concat_axis': concat_axis,
'dot_axes': dot_axes})
def _get_x(self, data):
x = []
for key in self._graph_inputs.keys():
if key not in data:
raise Exception('Expected to be provided an array '
'(in dict argument `data`) for input "' +
key + '".')
x.append(data[key])
return x
def _get_y(self, data):
y = []
for key in self._graph_outputs.keys():
if key not in data:
raise Exception('Expected to be provided an array '
'(in dict argument `data`) for output "' +
key + '".')
y.append(data[key])
return y
def fit(self, data, batch_size=32, nb_epoch=10, verbose=1, callbacks=[],
validation_split=0., validation_data=None, shuffle=True,
class_weight=None, sample_weight=None, **kwargs):
'''Trains the model for a fixed number of epochs.
Returns a history object. Its `history` attribute is a record of
training loss values at successive epochs,
as well as validation loss values (if applicable).
# Arguments
data: dictionary mapping input names and outputs names to
appropriate Numpy arrays. All arrays should contain
the same number of samples.
batch_size: int. Number of samples per gradient update.
nb_epoch: int.
verbose: 0 for no logging to stdout,
1 for progress bar logging, 2 for one log line per epoch.
callbacks: `keras.callbacks.Callback` list. List of callbacks
to apply during training. See [callbacks](callbacks.md).
validation_split: float (0. < x < 1). Fraction of the data to
use as held-out validation data.
validation_data: dictionary mapping input names and outputs names
to appropriate Numpy arrays to be used as
held-out validation data.
All arrays should contain the same number of samples.
Will override validation_split.
shuffle: boolean. Whether to shuffle the samples at each epoch.
class_weight: dictionary mapping output names to
class weight dictionaries.
sample_weight: dictionary mapping output names to
numpy arrays of sample weights.
'''
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
warnings.warn('The "show_accuracy" argument is deprecated, '
'instead you should pass the "accuracy" metric to '
'the model at compile time:\n'
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
str(kwargs))
x = self._get_x(data)
y = self._get_y(data)
if type(validation_data) is tuple:
raise Exception('Cannot used sample_weight with '
'validation data with legacy Graph model. '
'validation_data should be a dictionary.')
if validation_data:
val_x = self._get_x(validation_data)
val_y = self._get_y(validation_data)
validation_data = (val_x, val_y)
return super(Graph, self).fit(x, y,
batch_size=batch_size,
nb_epoch=nb_epoch,
verbose=verbose,
callbacks=callbacks,
validation_split=validation_split,
validation_data=validation_data,
shuffle=shuffle,
class_weight=class_weight,
sample_weight=sample_weight)
def evaluate(self, data, batch_size=128,
verbose=0, sample_weight={}, **kwargs):
'''Computes the loss on some input data, batch by batch.
Returns the scalar test loss over the data,
or a list of metrics values (starting with the test loss)
if applicable.
Arguments: see `fit` method.
'''
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
warnings.warn('The "show_accuracy" argument is deprecated, '
'instead you should pass the "accuracy" metric to '
'the model at compile time:\n'
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
str(kwargs))
x = self._get_x(data)
y = self._get_y(data)
return super(Graph, self).evaluate(x, y,
batch_size=batch_size,
verbose=verbose,
sample_weight=sample_weight)
def predict(self, data, batch_size=128, verbose=0):
'''Generates output predictions for the input samples
batch by batch.
Arguments: see `fit` method.
'''
x = self._get_x(data)
output_list = super(Graph, self).predict(x, batch_size=batch_size,
verbose=verbose)
if not isinstance(output_list, list):
output_list = [output_list]
return dict(zip(self._graph_outputs, output_list))
def train_on_batch(self, data,
class_weight={},
sample_weight={}, **kwargs):
'''Single gradient update on a batch of samples.
Returns the scalar train loss over the data,
or a list of metrics values (starting with the test loss)
if applicable.
Arguments: see `fit` method.
'''
if 'accuracy' in kwargs:
kwargs.pop('accuracy')
warnings.warn('The "accuracy" argument is deprecated, '
'instead you should pass the "accuracy" metric to '
'the model at compile time:\n'
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
str(kwargs))
x = self._get_x(data)
y = self._get_y(data)
return super(Graph, self).train_on_batch(x, y,
sample_weight=sample_weight,
class_weight=class_weight)
def test_on_batch(self, data, sample_weight={}, **kwargs):
'''Test the network on a single batch of samples.
Returns the scalar test loss over the data,
or a list of metrics values (starting with the test loss)
if applicable.
Arguments: see `fit` method.
'''
if 'accuracy' in kwargs:
kwargs.pop('accuracy')
warnings.warn('The "accuracy" argument is deprecated, '
'instead you should pass the "accuracy" metric to '
'the model at compile time:\n'
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
str(kwargs))
x = self._get_x(data)
y = self._get_y(data)
return super(Graph, self).test_on_batch(x, y,
sample_weight=sample_weight)
def predict_on_batch(self, data):
output_list = super(Graph, self).predict_on_batch(data)
if not isinstance(output_list, list):
output_list = [output_list]
return dict(zip(self._graph_outputs, output_list))
def fit_generator(self, generator, samples_per_epoch, nb_epoch,
verbose=1, callbacks=[],
validation_data=None, nb_val_samples=None,
class_weight={},
max_q_size=10, **kwargs):
'''Fits a model on data generated batch-by-batch by a Python generator.
The generator is run in parallel to the model, for efficiency.
For instance, this allows you to do real-time data augmentation
on images on CPU in parallel to training your model on GPU.
# Arguments
generator: a generator.
The output of the generator must be either a tuple
of dictionaries `(input_data, sample_weight)`
or a dictionary `input_data`
(mapping names of inputs and outputs to Numpy arrays).
All arrays should contain the same number of samples.
The generator is expected to loop over its data
indefinitely. An epoch finishes when `samples_per_epoch`
samples have been seen by the model.
samples_per_epoch: integer, number of samples to process before
going to the next epoch.
nb_epoch: integer, total number of iterations on the data.
verbose: verbosity mode, 0, 1, or 2.
callbacks: list of callbacks to be called during training.
validation_data: dictionary mapping input names and outputs names
to appropriate Numpy arrays to be used as
held-out validation data, or a generator yielding such
dictionaries. All arrays should contain the same number
of samples. If a generator, will be called until more than
`nb_val_samples` examples have been generated at the
end of every epoch. These examples will then be used
as the validation data.
nb_val_samples: number of samples to use from validation
generator at the end of every epoch.
class_weight: dictionary mapping class indices to a weight
for the class.
# Returns
A `History` object.
# Examples
```python
def generate_arrays_from_file(path):
while 1:
f = open(path)
for line in f:
# create Numpy arrays of input data
# and labels, from each line in the file
x1, x2, y = process_line(line)
yield ({'input_1': x1, 'input_2': x2, 'output': y})
f.close()
graph.fit_generator(generate_arrays_from_file('/my_file.txt'),
samples_per_epoch=10000, nb_epoch=10)
```
'''
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
warnings.warn('The "show_accuracy" argument is deprecated, '
'instead you should pass the "accuracy" metric to '
'the model at compile time:\n'
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if 'nb_worker' in kwargs:
kwargs.pop('nb_worker')
warnings.warn('The "nb_worker" argument is deprecated, '
'please remove it from your code.')
if 'nb_val_worker' in kwargs:
kwargs.pop('nb_val_worker')
warnings.warn('The "nb_val_worker" argument is deprecated, '
'please remove it from your code.')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
str(kwargs))
self._train_on_batch = self.train_on_batch
self.train_on_batch = super(Graph, self).train_on_batch
self._evaluate = self.evaluate
self.evaluate = super(Graph, self).evaluate
if validation_data and type(validation_data) is tuple:
raise Exception('Cannot use sample_weight with '
'validation_data in legacy Graph model.')
if validation_data and type(validation_data) is dict:
validation_data = (self._get_x(validation_data),
self._get_y(validation_data))
original_generator = generator
def fixed_generator():
while 1:
data = next(original_generator)
if type(data) is tuple:
data, sample_weight = data
x = self._get_x(data)
y = self._get_y(data)
yield x, y, sample_weight
else:
x = self._get_x(data)
y = self._get_y(data)
yield x, y
generator = fixed_generator()
history = super(Graph, self).fit_generator(generator,
samples_per_epoch,
nb_epoch,
verbose=verbose,
callbacks=callbacks,
validation_data=validation_data,
nb_val_samples=nb_val_samples,
class_weight=class_weight,
max_q_size=max_q_size)
self.train_on_batch = self._train_on_batch
self.evaluate = self._evaluate
return history
def evaluate_generator(self, generator, val_samples,
verbose=1, max_q_size=10, **kwargs):
'''Evaluates the model on a generator. The generator should
return the same kind of data with every yield as accepted
by `evaluate`.
If `show_accuracy`, it returns a tuple `(loss, accuracy)`,
otherwise it returns the loss value.
Arguments:
generator:
generator yielding dictionaries of the kind accepted
by `evaluate`, or tuples of such dictionaries and
associated dictionaries of sample weights.
val_samples:
total number of samples to generate from `generator`
to use in validation.
Other arguments are the same as for `fit`.
'''
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
warnings.warn('The "show_accuracy" argument is deprecated, '
'instead you should pass the "accuracy" metric to '
'the model at compile time:\n'
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if 'verbose' in kwargs:
kwargs.pop('verbose')
warnings.warn('The "verbose" argument is deprecated.')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
str(kwargs))
self._test_on_batch = self.test_on_batch
self.test_on_batch = super(Graph, self).test_on_batch
original_generator = generator
def fixed_generator():
while 1:
data = next(original_generator)
if type(data) is tuple:
data, sample_weight = data
x = self._get_x(data)
y = self._get_y(data)
yield x, y, sample_weight
else:
x = self._get_x(data)
y = self._get_y(data)
yield x, y
generator = fixed_generator()
history = super(Graph, self).evaluate_generator(generator,
val_samples,
max_q_size=max_q_size)
self.test_on_batch = self._test_on_batch
return history
# get_weights, set_weights: inherited
def get_config(self):
config = {'input_config': self._graph_input_config,
'node_config': self._graph_node_config,
'output_config': self._graph_output_config}
nodes = {}
for name, node in self._graph_nodes.items():
nodes[name] = {'class_name': node.__class__.__name__,
'config': node.get_config()}
if name in self._graph_shared_nodes_names:
nodes[name]['shared'] = True
config['nodes'] = nodes
return copy.deepcopy(config)
@classmethod
def from_config(cls, config):
# TODO: test legacy support
from keras.utils.layer_utils import layer_from_config
def normalize_legacy_config(conf):
if 'class_name' not in conf:
class_name = conf['name']
name = conf.get('custom_name')
conf['name'] = name
new_config = {
'class_name': class_name,
'config': conf,
}
return new_config
return conf
graph = cls()
inputs = config.get('input_config')
for input in inputs:
graph.add_input(**input)
nodes = config.get('node_config')
for node in nodes:
layer_config = config['nodes'][node['name']]
layer_config = normalize_legacy_config(layer_config)
if 'layer' in node:
# for add_shared_node
node['layer'] = layer_from_config(node['layer'])
else:
layer = layer_from_config(layer_config)
node['layer'] = layer
node['create_output'] = False # outputs will be added below
if layer_config.get('shared'):
graph.add_shared_node(**node)
else:
graph.add_node(**node)
outputs = config.get('output_config')
for output in outputs:
graph.add_output(**output)
return graph
def load_weights(self, fname):
if not self.built:
self.build()
super(Graph, self).load_weights(fname)
+141 -9
Ver Arquivo
@@ -1,84 +1,216 @@
import numpy as np
from . import backend as K
from .utils.generic_utils import get_from_module
def binary_accuracy(y_true, y_pred):
'''Calculates the mean accuracy rate across all predictions for binary
classification problems.
'''
return K.mean(K.equal(y_true, K.round(y_pred)))
def categorical_accuracy(y_true, y_pred):
'''Calculates the mean accuracy rate across all predictions for
multiclass classification problems.
'''
return K.mean(K.equal(K.argmax(y_true, axis=-1),
K.argmax(y_pred, axis=-1)))
def sparse_categorical_accuracy(y_true, y_pred):
'''Same as categorical_accuracy, but useful when the predictions are for
sparse targets.
'''
return K.mean(K.equal(K.max(y_true, axis=-1),
K.cast(K.argmax(y_pred, axis=-1), K.floatx())))
def top_k_categorical_accuracy(y_true, y_pred, k=5):
'''Calculates the top-k categorical accuracy rate, i.e. success when the
target class is within the top-k predictions provided.
'''
return K.mean(K.in_top_k(y_pred, K.argmax(y_true, axis=-1), k))
def mean_squared_error(y_true, y_pred):
'''Calculates the mean squared error (mse) rate
between predicted and target values.
'''
return K.mean(K.square(y_pred - y_true))
def mean_absolute_error(y_true, y_pred):
'''Calculates the mean absolute error (mae) rate
between predicted and target values.
'''
return K.mean(K.abs(y_pred - y_true))
def mean_absolute_percentage_error(y_true, y_pred):
'''Calculates the mean absolute percentage error (mape) rate
between predicted and target values.
'''
diff = K.abs((y_true - y_pred) / K.clip(K.abs(y_true), K.epsilon(), np.inf))
return 100. * K.mean(diff)
def mean_squared_logarithmic_error(y_true, y_pred):
'''Calculates the mean squared logarithmic error (msle) rate
between predicted and target values.
'''
first_log = K.log(K.clip(y_pred, K.epsilon(), np.inf) + 1.)
second_log = K.log(K.clip(y_true, K.epsilon(), np.inf) + 1.)
return K.mean(K.square(first_log - second_log))
def squared_hinge(y_true, y_pred):
return K.mean(K.square(K.maximum(1. - y_true * y_pred, 0.)))
def hinge(y_true, y_pred):
'''Calculates the hinge loss, which is defined as
`max(1 - y_true * y_pred, 0)`.
'''
return K.mean(K.maximum(1. - y_true * y_pred, 0.))
def squared_hinge(y_true, y_pred):
'''Calculates the squared value of the hinge loss.
'''
return K.mean(K.square(K.maximum(1. - y_true * y_pred, 0.)))
def categorical_crossentropy(y_true, y_pred):
'''Expects a binary class matrix instead of a vector of scalar classes.
'''Calculates the cross-entropy value for multiclass classification
problems. Note: Expects a binary class matrix instead of a vector
of scalar classes.
'''
return K.mean(K.categorical_crossentropy(y_pred, y_true))
def sparse_categorical_crossentropy(y_true, y_pred):
'''expects an array of integer classes.
Note: labels shape must have the same number of dimensions as output shape.
If you get a shape error, add a length-1 dimension to labels.
'''Calculates the cross-entropy value for multiclass classification
problems with sparse targets. Note: Expects an array of integer
classes. Labels shape must have the same number of dimensions as
output shape. If you get a shape error, add a length-1 dimension
to labels.
'''
return K.mean(K.sparse_categorical_crossentropy(y_pred, y_true))
def binary_crossentropy(y_true, y_pred):
'''Calculates the cross-entropy value for binary classification
problems.
'''
return K.mean(K.binary_crossentropy(y_pred, y_true))
def kullback_leibler_divergence(y_true, y_pred):
'''Calculates the Kullback-Leibler (KL) divergence between prediction
and target values.
'''
y_true = K.clip(y_true, K.epsilon(), 1)
y_pred = K.clip(y_pred, K.epsilon(), 1)
return K.sum(y_true * K.log(y_true / y_pred), axis=-1)
def poisson(y_true, y_pred):
'''Calculates the poisson function over prediction and target values.
'''
return K.mean(y_pred - y_true * K.log(y_pred + K.epsilon()))
def cosine_proximity(y_true, y_pred):
'''Calculates the cosine similarity between the prediction and target
values.
'''
y_true = K.l2_normalize(y_true, axis=-1)
y_pred = K.l2_normalize(y_pred, axis=-1)
return -K.mean(y_true * y_pred)
def matthews_correlation(y_true, y_pred):
'''Calculates the Matthews correlation coefficient measure for quality
of binary classification problems.
'''
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(y_neg * y_pred_pos)
fn = K.sum(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())
def precision(y_true, y_pred):
'''Calculates the precision, a metric for multi-label classification of
how many selected items are relevant.
'''
true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1)))
predicted_positives = K.sum(K.round(K.clip(y_pred, 0, 1)))
precision = true_positives / (predicted_positives + K.epsilon())
return precision
def recall(y_true, y_pred):
'''Calculates the recall, a metric for multi-label classification of
how many relevant items are selected.
'''
true_positives = K.sum(K.round(K.clip(y_true * y_pred, 0, 1)))
possible_positives = K.sum(K.round(K.clip(y_true, 0, 1)))
recall = true_positives / (possible_positives + K.epsilon())
return recall
def fbeta_score(y_true, y_pred, beta=1):
'''Calculates the F score, the weighted harmonic mean of precision and recall.
This is useful for multi-label classification, where input samples can be
classified as sets of labels. By only using accuracy (precision) a model
would achieve a perfect score by simply assigning every class to every
input. In order to avoid this, a metric should penalize incorrect class
assignments as well (recall). The F-beta score (ranged from 0.0 to 1.0)
computes this, as a weighted mean of the proportion of correct class
assignments vs. the proportion of incorrect class assignments.
With beta = 1, this is equivalent to a F-measure. With beta < 1, assigning
correct classes becomes more important, and with beta > 1 the metric is
instead weighted towards penalizing incorrect class assignments.
'''
if beta < 0:
raise ValueError('The lowest choosable beta is zero (only precision).')
# If there are no true positives, fix the F score at 0 like sklearn.
if K.sum(K.round(K.clip(y_true, 0, 1))) == 0:
return 0
p = precision(y_true, y_pred)
r = recall(y_true, y_pred)
bb = beta ** 2
fbeta_score = (1 + bb) * (p * r) / (bb * p + r + K.epsilon())
return fbeta_score
def fmeasure(y_true, y_pred):
'''Calculates the f-measure, the harmonic mean of precision and recall.
'''
return fbeta_score(y_true, y_pred, beta=1)
# aliases
mse = MSE = mean_squared_error
mae = MAE = mean_absolute_error
mape = MAPE = mean_absolute_percentage_error
msle = MSLE = mean_squared_logarithmic_error
cosine = cosine_proximity
fscore = f1score = fmeasure
from .utils.generic_utils import get_from_module
def get(identifier):
return get_from_module(identifier, globals(), 'metric')
+160 -105
Ver Arquivo
@@ -6,11 +6,11 @@ import os
import numpy as np
from . import backend as K
from . import optimizers
from .utils.io_utils import ask_to_proceed_with_overwrite
from .engine.training import Model
from .engine.topology import get_source_inputs, Node
from .engine.topology import get_source_inputs, Node, Layer, Merge
from .optimizers import optimizer_from_config
from .legacy.models import Graph
def save_model(model, filepath, overwrite=True):
@@ -27,7 +27,7 @@ def save_model(model, filepath, overwrite=True):
return obj.item()
# misc functions (e.g. loss function)
if hasattr(obj, '__call__'):
if callable(obj):
return obj.__name__
# if obj is a python 'type'
@@ -56,40 +56,52 @@ def save_model(model, filepath, overwrite=True):
model.save_weights_to_hdf5_group(model_weights_group)
if hasattr(model, 'optimizer'):
f.attrs['training_config'] = json.dumps({
'optimizer_config': {
'class_name': model.optimizer.__class__.__name__,
'config': model.optimizer.get_config()
},
'loss': model.loss,
'metrics': model.metrics,
'sample_weight_mode': model.sample_weight_mode,
'loss_weights': model.loss_weights,
}, default=get_json_type).encode('utf8')
if isinstance(model.optimizer, optimizers.TFOptimizer):
warnings.warn(
'TensorFlow optimizers do not '
'make it possible to access '
'optimizer attributes or optimizer state '
'after instantiation. '
'As a result, we cannot save the optimizer '
'as part of the model save file.'
'You will have to compile your model again after loading it. '
'Prefer using a Keras optimizer instead '
'(see keras.io/optimizers).')
else:
f.attrs['training_config'] = json.dumps({
'optimizer_config': {
'class_name': model.optimizer.__class__.__name__,
'config': model.optimizer.get_config()
},
'loss': model.loss,
'metrics': model.metrics,
'sample_weight_mode': model.sample_weight_mode,
'loss_weights': model.loss_weights,
}, default=get_json_type).encode('utf8')
# save optimizer weights
symbolic_weights = getattr(model.optimizer, 'weights')
if symbolic_weights:
optimizer_weights_group = f.create_group('optimizer_weights')
weight_values = K.batch_get_value(symbolic_weights)
weight_names = []
for i, (w, val) in enumerate(zip(symbolic_weights, weight_values)):
if hasattr(w, 'name') and w.name:
name = str(w.name)
else:
name = 'param_' + str(i)
weight_names.append(name.encode('utf8'))
optimizer_weights_group.attrs['weight_names'] = weight_names
for name, val in zip(weight_names, weight_values):
param_dset = optimizer_weights_group.create_dataset(
name,
val.shape,
dtype=val.dtype)
if not val.shape:
# scalar
param_dset[()] = val
else:
param_dset[:] = val
# save optimizer weights
symbolic_weights = getattr(model.optimizer, 'weights')
if symbolic_weights:
optimizer_weights_group = f.create_group('optimizer_weights')
weight_values = K.batch_get_value(symbolic_weights)
weight_names = []
for i, (w, val) in enumerate(zip(symbolic_weights, weight_values)):
if hasattr(w, 'name') and w.name:
name = str(w.name)
else:
name = 'param_' + str(i)
weight_names.append(name.encode('utf8'))
optimizer_weights_group.attrs['weight_names'] = weight_names
for name, val in zip(weight_names, weight_values):
param_dset = optimizer_weights_group.create_dataset(
name,
val.shape,
dtype=val.dtype)
if not val.shape:
# scalar
param_dset[()] = val
else:
param_dset[:] = val
f.flush()
f.close()
@@ -97,7 +109,7 @@ def save_model(model, filepath, overwrite=True):
def load_model(filepath, custom_objects={}):
def deserialize(obj):
if type(obj) is list:
if isinstance(obj, list):
deserialized = []
for value in obj:
if value in custom_objects:
@@ -105,7 +117,7 @@ def load_model(filepath, custom_objects={}):
else:
deserialized.append(value)
return deserialized
if type(obj) is dict:
if isinstance(obj, dict):
deserialized = {}
for key, value in obj.items():
if value in custom_objects:
@@ -139,7 +151,7 @@ def load_model(filepath, custom_objects={}):
return model
training_config = json.loads(training_config.decode('utf-8'))
optimizer_config = training_config['optimizer_config']
optimizer = optimizer_from_config(optimizer_config)
optimizer = optimizer_from_config(optimizer_config, custom_objects=custom_objects)
# recover loss functions and metrics
loss = deserialize(training_config['loss'])
@@ -157,7 +169,7 @@ def load_model(filepath, custom_objects={}):
# set optimizer weights
if 'optimizer_weights' in f:
# build train function (to get weight updates)
if model.__class__.__name__ == 'Sequential':
if isinstance(model, Sequential):
model.model._make_train_function()
else:
model._make_train_function()
@@ -172,8 +184,9 @@ def load_model(filepath, custom_objects={}):
def model_from_config(config, custom_objects={}):
from keras.utils.layer_utils import layer_from_config
if isinstance(config, list):
raise Exception('`model_fom_config` expects a dictionary, not a list. '
'Maybe you meant to use `Sequential.from_config(config)`?')
raise TypeError('`model_fom_config` expects a dictionary, not a list. '
'Maybe you meant to use '
'`Sequential.from_config(config)`?')
return layer_from_config(config, custom_objects=custom_objects)
@@ -238,7 +251,7 @@ class Sequential(Model):
self.model = None # internal Model instance
self.inputs = [] # tensors
self.outputs = [] # tensors (length 1)
self.trainable = True
self._trainable = True
# model attributes
self.inbound_nodes = []
@@ -260,14 +273,19 @@ class Sequential(Model):
# Arguments
layer: layer instance.
'''
if not isinstance(layer, Layer):
raise TypeError('The added layer must be '
'an instance of class Layer. '
'Found: ' + str(layer))
if not self.outputs:
# first layer in model: check that it is an input layer
if len(layer.inbound_nodes) == 0:
# create an input layer
if not hasattr(layer, 'batch_input_shape'):
raise Exception('The first layer in a Sequential model must '
'get an `input_shape` or '
'`batch_input_shape` argument.')
raise ValueError('The first layer in a '
'Sequential model must '
'get an `input_shape` or '
'`batch_input_shape` argument.')
batch_input_shape = layer.batch_input_shape
if hasattr(layer, 'input_dtype'):
input_dtype = layer.input_dtype
@@ -276,17 +294,18 @@ class Sequential(Model):
layer.create_input_layer(batch_input_shape, input_dtype)
if len(layer.inbound_nodes) != 1:
raise Exception('A layer added to a Sequential model must '
'not already be connected somewhere else. '
'Model received layer ' + layer.name +
' which has ' + str(len(layer.inbound_nodes)) +
' pre-existing inbound connections.')
raise ValueError('A layer added to a Sequential model must '
'not already be connected somewhere else. '
'Model received layer ' + layer.name +
' which has ' +
str(len(layer.inbound_nodes)) +
' pre-existing inbound connections.')
if len(layer.inbound_nodes[0].output_tensors) != 1:
raise Exception('All layers in a Sequential model '
'should have a single output tensor. '
'For multi-output layers, '
'use the functional API.')
raise ValueError('All layers in a Sequential model '
'should have a single output tensor. '
'For multi-output layers, '
'use the functional API.')
self.outputs = [layer.inbound_nodes[0].output_tensors[0]]
self.inputs = get_source_inputs(self.outputs[0])
@@ -306,8 +325,8 @@ class Sequential(Model):
output_shapes=[self.outputs[0]._keras_shape])
else:
output_tensor = layer(self.outputs[0])
if type(output_tensor) is list:
raise Exception('All layers in a Sequential model '
if isinstance(output_tensor, list):
raise TypeError('All layers in a Sequential model '
'should have a single output tensor. '
'For multi-output layers, '
'use the functional API.')
@@ -324,7 +343,7 @@ class Sequential(Model):
'''Removes the last layer in the model.
'''
if not self.layers:
raise Exception('There are no layers in the model.')
raise TypeError('There are no layers in the model.')
self.layers.pop()
if not self.layers:
@@ -363,10 +382,12 @@ class Sequential(Model):
def build(self, input_shape=None):
if not self.inputs or not self.outputs:
raise Exception('Sequential model cannot be built: model is empty.'
raise TypeError('Sequential model cannot be built: model is empty.'
' Add some layers first.')
# actually create the model
self.model = Model(self.inputs, self.outputs[0], name=self.name + '_model')
self.model = Model(self.inputs, self.outputs[0],
name=self.name + '_model')
self.model.trainable = self.trainable
# mirror model attributes
self.supports_masking = self.model.supports_masking
@@ -400,26 +421,27 @@ class Sequential(Model):
if self._flattened_layers is not None:
return self._flattened_layers
layers = []
if self.layers[0].__class__.__name__ == 'Merge':
merge = self.layers[0]
for layer in merge.layers:
if hasattr(layer, 'flattened_layers'):
for sublayer in layer.flattened_layers:
if sublayer not in layers:
layers.append(sublayer)
elif hasattr(layer, 'layers'):
for sublayer in layer.layers:
if sublayer not in layers:
layers.append(sublayer)
else:
if layer not in layers:
layers.append(layer)
else:
if self.layers[0] not in layers:
layers.append(self.layers[0])
for layer in self.layers[1:]:
if layer not in layers:
layers.append(layer)
if self.layers:
if isinstance(self.layers[0], Merge):
merge = self.layers[0]
for layer in merge.layers:
if hasattr(layer, 'flattened_layers'):
for sublayer in layer.flattened_layers:
if sublayer not in layers:
layers.append(sublayer)
elif hasattr(layer, 'layers'):
for sublayer in layer.layers:
if sublayer not in layers:
layers.append(sublayer)
else:
if layer not in layers:
layers.append(layer)
else:
if self.layers[0] not in layers:
layers.append(self.layers[0])
for layer in self.layers[1:]:
if layer not in layers:
layers.append(layer)
self._flattened_layers = layers
return layers
@@ -437,6 +459,16 @@ class Sequential(Model):
list(layer_dict.items()))
return all_attrs
@property
def trainable(self):
return self._trainable
@trainable.setter
def trainable(self, value):
if self.model:
self.model.trainable = value
self._trainable = value
@property
def trainable_weights(self):
if not self.trainable:
@@ -455,13 +487,22 @@ class Sequential(Model):
@property
def updates(self):
# support for legacy behavior
return self._gather_list_attr('updates')
return self.model.updates
@property
def state_updates(self):
# support for legacy behavior
return self._gather_list_attr('state_updates')
return self.model.state_updates
def get_updates_for(self, inputs):
return self.model.get_updates_for(inputs)
@property
def losses(self):
return self.model.losses
def get_losses_for(self, inputs):
return self.model.get_losses_for(inputs)
@property
def regularizers(self):
@@ -517,6 +558,7 @@ class Sequential(Model):
metrics: list of metrics to be evaluated by the model
during training and testing.
Typically you will use `metrics=['accuracy']`.
See [metrics](/metrics).
sample_weight_mode: if you need to do timestep-wise
sample weighting (2D weights), set this to "temporal".
"None" defaults to sample-wise weights (1D).
@@ -571,7 +613,8 @@ class Sequential(Model):
See [callbacks](/callbacks).
validation_split: float (0. < x < 1).
Fraction of the data to use as held-out validation data.
validation_data: tuple (X, y) to be used as held-out
validation_data: tuple (x_val, y_val) or tuple
(x_val, y_val, val_sample_weights) to be used as held-out
validation data. Will override validation_split.
shuffle: boolean or str (for 'batch').
Whether to shuffle the samples at each epoch.
@@ -597,7 +640,8 @@ class Sequential(Model):
and validation metrics values (if applicable).
'''
if self.model is None:
raise Exception('The model needs to be compiled before being used.')
raise RuntimeError('The model needs to be compiled '
'before being used.')
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
warnings.warn('The "show_accuracy" argument is deprecated, '
@@ -606,7 +650,7 @@ class Sequential(Model):
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
raise TypeError('Received unknown keyword arguments: ' +
str(kwargs))
return self.model.fit(x, y,
batch_size=batch_size,
@@ -638,7 +682,8 @@ class Sequential(Model):
the display labels for the scalar outputs.
'''
if self.model is None:
raise Exception('The model needs to be compiled before being used.')
raise RuntimeError('The model needs to be compiled '
'before being used.')
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
warnings.warn('The "show_accuracy" argument is deprecated, '
@@ -647,7 +692,7 @@ class Sequential(Model):
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
raise TypeError('Received unknown keyword arguments: ' +
str(kwargs))
return self.model.evaluate(x, y,
batch_size=batch_size,
@@ -696,7 +741,8 @@ class Sequential(Model):
the display labels for the scalar outputs.
'''
if self.model is None:
raise Exception('The model needs to be compiled before being used.')
raise RuntimeError('The model needs to be compiled '
'before being used.')
if 'accuracy' in kwargs:
kwargs.pop('accuracy')
warnings.warn('The "accuracy" argument is deprecated, '
@@ -705,7 +751,7 @@ class Sequential(Model):
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
raise TypeError('Received unknown keyword arguments: ' +
str(kwargs))
return self.model.train_on_batch(x, y,
sample_weight=sample_weight,
@@ -728,7 +774,8 @@ class Sequential(Model):
the display labels for the scalar outputs.
'''
if self.model is None:
raise Exception('The model needs to be compiled before being used.')
raise RuntimeError('The model needs to be compiled '
'before being used.')
if 'accuracy' in kwargs:
kwargs.pop('accuracy')
warnings.warn('The "accuracy" argument is deprecated, '
@@ -737,7 +784,7 @@ class Sequential(Model):
'`model.compile(optimizer, loss, '
'metrics=["accuracy"])`')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
raise TypeError('Received unknown keyword arguments: ' +
str(kwargs))
return self.model.test_on_batch(x, y,
sample_weight=sample_weight)
@@ -785,7 +832,8 @@ class Sequential(Model):
def fit_generator(self, generator, samples_per_epoch, nb_epoch,
verbose=1, callbacks=[],
validation_data=None, nb_val_samples=None,
class_weight=None, max_q_size=10, nb_worker=1, pickle_safe=False, **kwargs):
class_weight=None, max_q_size=10, nb_worker=1,
pickle_safe=False, **kwargs):
'''Fits the model on data generated batch-by-batch by
a Python generator.
The generator is run in parallel to the model, for efficiency.
@@ -843,9 +891,11 @@ class Sequential(Model):
```
'''
if self.model is None:
raise Exception('The model needs to be compiled before being used.')
raise RuntimeError('The model needs to be compiled '
'before being used.')
if nb_worker > 1 and not pickle_safe:
warnings.warn('The "nb_worker" argument is deprecated when pickle_safe is False')
warnings.warn('The "nb_worker" argument is deprecated '
'when pickle_safe is False')
nb_worker = 1 # For backward compatibility
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
@@ -859,7 +909,7 @@ class Sequential(Model):
warnings.warn('The "nb_val_worker" argument is deprecated, '
'please remove it from your code.')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
raise TypeError('Received unknown keyword arguments: ' +
str(kwargs))
return self.model.fit_generator(generator,
samples_per_epoch,
@@ -873,11 +923,13 @@ class Sequential(Model):
nb_worker=nb_worker,
pickle_safe=pickle_safe)
def evaluate_generator(self, generator, val_samples, max_q_size=10, nb_worker=1, pickle_safe=False, **kwargs):
def evaluate_generator(self, generator, val_samples,
max_q_size=10, nb_worker=1,
pickle_safe=False, **kwargs):
'''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)
@@ -892,9 +944,11 @@ class Sequential(Model):
easily to children processes.
'''
if self.model is None:
raise Exception('The model needs to be compiled before being used.')
raise RuntimeError('The model needs to be compiled '
'before being used.')
if nb_worker > 1 and not pickle_safe:
warnings.warn('The "nb_worker" argument is deprecated when pickle_safe is False')
warnings.warn('The "nb_worker" argument is deprecated '
'when pickle_safe is False')
nb_worker = 1 # For backward compatibility
if 'show_accuracy' in kwargs:
kwargs.pop('show_accuracy')
@@ -907,7 +961,7 @@ class Sequential(Model):
kwargs.pop('verbose')
warnings.warn('The "verbose" argument is deprecated.')
if kwargs:
raise Exception('Received unknown keyword arguments: ' +
raise TypeError('Received unknown keyword arguments: ' +
str(kwargs))
return self.model.evaluate_generator(generator,
val_samples,
@@ -915,7 +969,8 @@ class Sequential(Model):
nb_worker=nb_worker,
pickle_safe=pickle_safe)
def predict_generator(self, generator, val_samples, max_q_size=10, nb_worker=1, pickle_safe=False):
def predict_generator(self, generator, val_samples,
max_q_size=10, nb_worker=1, pickle_safe=False):
'''Generates predictions for the input samples from a data generator.
The generator should return the same kind of data as accepted by
`predict_on_batch`.
@@ -937,7 +992,8 @@ class Sequential(Model):
if self.model is None:
self.build()
if nb_worker > 1 and not pickle_safe:
warnings.warn('The "nb_worker" argument is deprecated when pickle_safe is False')
warnings.warn('The "nb_worker" argument is deprecated '
'when pickle_safe is False')
nb_worker = 1 # For backward compatibility
return self.model.predict_generator(generator, val_samples,
max_q_size=max_q_size,
@@ -949,7 +1005,7 @@ class Sequential(Model):
as a Python list.
'''
config = []
if self.layers[0].__class__.__name__ == 'Merge':
if isinstance(self.layers[0], Merge):
assert hasattr(self.layers[0], 'layers')
layers = []
for layer in self.layers[0].layers:
@@ -973,7 +1029,6 @@ class Sequential(Model):
'''
from keras.utils.layer_utils import layer_from_config
from keras.layers import Merge
assert type(config) is list
if not layer_cache:
layer_cache = {}
+2 -1
Ver Arquivo
@@ -1,6 +1,7 @@
from __future__ import absolute_import
import numpy as np
from . import backend as K
from .utils.generic_utils import get_from_module
def mean_squared_error(y_true, y_pred):
@@ -72,6 +73,6 @@ msle = MSLE = mean_squared_logarithmic_error
kld = KLD = kullback_leibler_divergence
cosine = cosine_proximity
from .utils.generic_utils import get_from_module
def get(identifier):
return get_from_module(identifier, globals(), 'objective')
+103 -25
Ver Arquivo
@@ -19,6 +19,7 @@ def optimizer_from_config(config, custom_objects={}):
'adam': Adam,
'adamax': Adamax,
'nadam': Nadam,
'tfoptimizer': TFOptimizer,
}
class_name = config['class_name']
if class_name in custom_objects:
@@ -47,20 +48,12 @@ class Optimizer(object):
allowed_kwargs = {'clipnorm', 'clipvalue'}
for k in kwargs:
if k not in allowed_kwargs:
raise Exception('Unexpected keyword argument '
raise TypeError('Unexpected keyword argument '
'passed to optimizer: ' + str(k))
self.__dict__.update(kwargs)
self.updates = []
self.weights = []
def get_state(self):
return [K.get_value(u[0]) for u in self.updates]
def set_state(self, value_list):
assert len(self.updates) == len(value_list)
for u, v in zip(self.updates, value_list):
K.set_value(u[0], v)
def get_updates(self, params, constraints, loss):
raise NotImplementedError
@@ -91,10 +84,10 @@ class Optimizer(object):
param_values = K.batch_get_value(params)
for pv, p, w in zip(param_values, params, weights):
if pv.shape != w.shape:
raise Exception('Optimizer weight shape ' +
str(pv.shape) +
' not compatible with '
'provided weight shape ' + str(w.shape))
raise ValueError('Optimizer weight shape ' +
str(pv.shape) +
' not compatible with '
'provided weight shape ' + str(w.shape))
weight_value_tuples.append((p, w))
K.batch_set_value(weight_value_tuples)
@@ -135,11 +128,16 @@ 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 +183,17 @@ 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 +202,16 @@ 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:
@@ -215,6 +223,7 @@ class RMSprop(Optimizer):
def get_config(self):
config = {'lr': float(K.get_value(self.lr)),
'rho': float(K.get_value(self.rho)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon}
base_config = super(RMSprop, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
@@ -233,10 +242,13 @@ 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 +257,15 @@ 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]
@@ -258,6 +275,7 @@ class Adagrad(Optimizer):
def get_config(self):
config = {'lr': float(K.get_value(self.lr)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon}
base_config = super(Adagrad, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
@@ -278,10 +296,14 @@ 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 +313,11 @@ 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 +326,7 @@ 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]
@@ -314,6 +341,7 @@ class Adadelta(Optimizer):
def get_config(self):
config = {'lr': float(K.get_value(self.lr)),
'rho': self.rho,
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon}
base_config = super(Adadelta, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
@@ -333,20 +361,26 @@ 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]
@@ -373,6 +407,7 @@ class Adam(Optimizer):
config = {'lr': float(K.get_value(self.lr)),
'beta_1': float(K.get_value(self.beta_1)),
'beta_2': float(K.get_value(self.beta_2)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon}
base_config = super(Adam, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
@@ -393,20 +428,26 @@ 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))
lr_t = lr / (1. - K.pow(self.beta_1, t))
shapes = [K.get_variable_shape(p) for p in params]
# zero init of 1st moment
@@ -436,6 +477,7 @@ class Adamax(Optimizer):
config = {'lr': float(K.get_value(self.lr)),
'beta_1': float(K.get_value(self.beta_1)),
'beta_2': float(K.get_value(self.beta_2)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon}
base_config = super(Adamax, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
@@ -521,6 +563,36 @@ class Nadam(Optimizer):
return dict(list(base_config.items()) + list(config.items()))
class TFOptimizer(Optimizer):
def __init__(self, optimizer):
self.optimizer = optimizer
self.iterations = K.variable(0.)
self.updates = []
def get_updates(self, params, constraints, loss):
if constraints:
raise ValueError('TF optimizers do not support '
'weights constraints. Either remove '
'all weights constraints in your model, '
'or use a Keras optimizer.')
grads = self.optimizer.compute_gradients(loss, params)
opt_update = self.optimizer.apply_gradients(
grads, global_step=self.iterations)
self.updates.append(opt_update)
return self.updates
@property
def weights(self):
raise NotImplementedError
def get_config(self):
raise NotImplementedError
def from_config(self, config):
raise NotImplementedError
# aliases
sgd = SGD
rmsprop = RMSprop
@@ -532,5 +604,11 @@ nadam = Nadam
def get(identifier, kwargs=None):
if K.backend() == 'tensorflow':
# Wrap TF optimizer instances
import tensorflow as tf
if isinstance(identifier, tf.train.Optimizer):
return TFOptimizer(identifier)
# Instantiate a Keras optimizer
return get_from_module(identifier, globals(), 'optimizer',
instantiate=True, kwargs=kwargs)
+159 -60
Ver Arquivo
@@ -12,6 +12,7 @@ import scipy.ndimage as ndi
from six.moves import range
import os
import threading
import warnings
from .. import backend as K
@@ -59,8 +60,8 @@ def random_shear(x, intensity, row_index=1, col_index=2, channel_index=0,
def random_zoom(x, zoom_range, row_index=1, col_index=2, channel_index=0,
fill_mode='nearest', cval=0.):
if len(zoom_range) != 2:
raise Exception('zoom_range should be a tuple or list of two floats. '
'Received arg: ', zoom_range)
raise ValueError('zoom_range should be a tuple or list of two floats. '
'Received arg: ', zoom_range)
if zoom_range[0] == 1 and zoom_range[1] == 1:
zx, zy = 1, 1
@@ -120,8 +121,19 @@ def flip_axis(x, axis):
def array_to_img(x, dim_ordering='default', scale=True):
from PIL import Image
x = np.asarray(x)
if x.ndim != 3:
raise ValueError('Expected image array to have rank 3 (single image). '
'Got array with shape:', x.shape)
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
if dim_ordering not in {'th', 'tf'}:
raise ValueError('Invalid dim_ordering:', dim_ordering)
# Original Numpy array x has format (height, width, channel)
# or (channel, height, width)
# but target PIL image has format (width, height, channel)
if dim_ordering == 'th':
x = x.transpose(1, 2, 0)
if scale:
@@ -137,15 +149,17 @@ def array_to_img(x, dim_ordering='default', scale=True):
# grayscale
return Image.fromarray(x[:, :, 0].astype('uint8'), 'L')
else:
raise Exception('Unsupported channel number: ', x.shape[2])
raise ValueError('Unsupported channel number: ', x.shape[2])
def img_to_array(img, dim_ordering='default'):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
if dim_ordering not in ['th', 'tf']:
raise Exception('Unknown dim_ordering: ', dim_ordering)
# image has dim_ordering (height, width, channel)
if dim_ordering not in {'th', 'tf'}:
raise ValueError('Unknown dim_ordering: ', dim_ordering)
# Numpy array x has format (height, width, channel)
# or (channel, height, width)
# but original PIL image has format (width, height, channel)
x = np.asarray(img, dtype='float32')
if len(x.shape) == 3:
if dim_ordering == 'th':
@@ -156,11 +170,19 @@ def img_to_array(img, dim_ordering='default'):
else:
x = x.reshape((x.shape[0], x.shape[1], 1))
else:
raise Exception('Unsupported image shape: ', x.shape)
raise ValueError('Unsupported image shape: ', x.shape)
return x
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:
@@ -173,8 +195,9 @@ def load_img(path, grayscale=False, target_size=None):
def list_pictures(directory, ext='jpg|jpeg|bmp|png'):
return [os.path.join(directory, f) for f in os.listdir(directory)
if os.path.isfile(os.path.join(directory, f)) and re.match('([\w]+\.(?:' + ext + '))', f)]
return [os.path.join(root, f)
for root, dirs, files in os.walk(directory) for f in files
if re.match('([\w]+\.(?:' + ext + '))', f)]
class ImageDataGenerator(object):
@@ -203,8 +226,12 @@ class ImageDataGenerator(object):
horizontal_flip: whether to randomly flip images horizontally.
vertical_flip: whether to randomly flip images vertically.
rescale: rescaling factor. If None or 0, no rescaling is applied,
otherwise we multiply the data by the value provided (before applying
any other transformation).
otherwise we multiply the data by the value provided
(before applying any other transformation).
preprocessing_function: function that will be implied on each input.
The function will run before any other modification on it.
The function should take one argument: one image (Numpy tensor with rank 3),
and should output a Numpy tensor with the same shape.
dim_ordering: 'th' or 'tf'. In 'th' mode, the channels dimension
(the depth) is at index 1, in 'tf' mode it is at index 3.
It defaults to the `image_dim_ordering` value found in your
@@ -228,6 +255,7 @@ class ImageDataGenerator(object):
horizontal_flip=False,
vertical_flip=False,
rescale=None,
preprocessing_function=None,
dim_ordering='default'):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
@@ -236,11 +264,12 @@ class ImageDataGenerator(object):
self.std = None
self.principal_components = None
self.rescale = rescale
self.preprocessing_function = preprocessing_function
if dim_ordering not in {'tf', 'th'}:
raise Exception('dim_ordering should be "tf" (channel after row and '
'column) or "th" (channel before row and column). '
'Received arg: ', dim_ordering)
raise ValueError('dim_ordering should be "tf" (channel after row and '
'column) or "th" (channel before row and column). '
'Received arg: ', dim_ordering)
self.dim_ordering = dim_ordering
if dim_ordering == 'th':
self.channel_index = 1
@@ -256,9 +285,9 @@ class ImageDataGenerator(object):
elif len(zoom_range) == 2:
self.zoom_range = [zoom_range[0], zoom_range[1]]
else:
raise Exception('zoom_range should be a float or '
'a tuple or list of two floats. '
'Received arg: ', zoom_range)
raise ValueError('zoom_range should be a float or '
'a tuple or list of two floats. '
'Received arg: ', zoom_range)
def flow(self, X, y=None, batch_size=32, shuffle=True, seed=None,
save_to_dir=None, save_prefix='', save_format='jpeg'):
@@ -272,16 +301,20 @@ class ImageDataGenerator(object):
target_size=(256, 256), color_mode='rgb',
classes=None, class_mode='categorical',
batch_size=32, shuffle=True, seed=None,
save_to_dir=None, save_prefix='', save_format='jpeg'):
save_to_dir=None, save_prefix='', save_format='jpeg',
follow_links=False):
return DirectoryIterator(
directory, self,
target_size=target_size, color_mode=color_mode,
classes=classes, class_mode=class_mode,
dim_ordering=self.dim_ordering,
batch_size=batch_size, shuffle=shuffle, seed=seed,
save_to_dir=save_to_dir, save_prefix=save_prefix, save_format=save_format)
save_to_dir=save_to_dir, save_prefix=save_prefix, save_format=save_format,
follow_links=follow_links)
def standardize(self, x):
if self.preprocessing_function:
x = self.preprocessing_function(x)
if self.rescale:
x *= self.rescale
# x is a single image, so it doesn't have image number at index 0
@@ -292,15 +325,31 @@ class ImageDataGenerator(object):
x /= (np.std(x, axis=img_channel_index, keepdims=True) + 1e-7)
if self.featurewise_center:
x -= self.mean
if self.mean is not None:
x -= self.mean
else:
warnings.warn('This ImageDataGenerator specifies '
'`featurewise_center`, but it hasn\'t'
'been fit on any training data. Fit it '
'first by calling `.fit(numpy_data)`.')
if self.featurewise_std_normalization:
x /= (self.std + 1e-7)
if self.std is not None:
x /= (self.std + 1e-7)
else:
warnings.warn('This ImageDataGenerator specifies '
'`featurewise_std_normalization`, but it hasn\'t'
'been fit on any training data. Fit it '
'first by calling `.fit(numpy_data)`.')
if self.zca_whitening:
flatx = np.reshape(x, (x.size))
whitex = np.dot(flatx, self.principal_components)
x = np.reshape(whitex, (x.shape[0], x.shape[1], x.shape[2]))
if self.principal_components is not None:
flatx = np.reshape(x, (x.size))
whitex = np.dot(flatx, self.principal_components)
x = np.reshape(whitex, (x.shape[0], x.shape[1], x.shape[2]))
else:
warnings.warn('This ImageDataGenerator specifies '
'`zca_whitening`, but it hasn\'t'
'been fit on any training data. Fit it '
'first by calling `.fit(numpy_data)`.')
return x
def random_transform(self, x):
@@ -376,12 +425,31 @@ class ImageDataGenerator(object):
and zca_whitening.
# Arguments
X: Numpy array, the data to fit on.
augment: whether to fit on randomly augmented samples
rounds: if `augment`,
X: Numpy array, the data to fit on. Should have rank 4.
In case of grayscale data,
the channels axis should have value 1, and in case
of RGB data, it should have value 3.
augment: Whether to fit on randomly augmented samples
rounds: If `augment`,
how many augmentation passes to do over the data
seed: random seed.
'''
X = np.asarray(X)
if X.ndim != 4:
raise ValueError('Input to `.fit()` should have rank 4. '
'Got array with shape: ' + str(X.shape))
if X.shape[self.channel_index] not in {1, 3, 4}:
raise ValueError(
'Expected input to be images (as Numpy array) '
'following the dimension ordering convention "' + self.dim_ordering + '" '
'(channels on axis ' + str(self.channel_index) + '), i.e. expected '
'either 1, 3 or 4 channels on axis ' + str(self.channel_index) + '. '
'However, it was passed an array with shape ' + str(X.shape) +
' (' + str(X.shape[self.channel_index]) + ' channels).')
if seed is not None:
np.random.seed(seed)
X = np.copy(X)
if augment:
aX = np.zeros(tuple([rounds * X.shape[0]] + list(X.shape)[1:]))
@@ -391,16 +459,22 @@ class ImageDataGenerator(object):
X = aX
if self.featurewise_center:
self.mean = np.mean(X, axis=0)
self.mean = np.mean(X, axis=(0, self.row_index, self.col_index))
broadcast_shape = [1, 1, 1]
broadcast_shape[self.channel_index - 1] = X.shape[self.channel_index]
self.mean = np.reshape(self.mean, broadcast_shape)
X -= self.mean
if self.featurewise_std_normalization:
self.std = np.std(X, axis=0)
X /= (self.std + 1e-7)
self.std = np.std(X, axis=(0, self.row_index, self.col_index))
broadcast_shape = [1, 1, 1]
broadcast_shape[self.channel_index - 1] = X.shape[self.channel_index]
self.std = np.reshape(self.std, broadcast_shape)
X /= (self.std + K.epsilon())
if self.zca_whitening:
flatX = np.reshape(X, (X.shape[0], X.shape[1] * X.shape[2] * X.shape[3]))
sigma = np.dot(flatX.T, flatX) / flatX.shape[1]
sigma = np.dot(flatX.T, flatX) / flatX.shape[0]
U, S, V = linalg.svd(sigma)
self.principal_components = np.dot(np.dot(U, np.diag(1. / np.sqrt(S + 10e-7))), U.T)
@@ -423,11 +497,11 @@ class Iterator(object):
# ensure self.batch_index is 0
self.reset()
while 1:
if seed is not None:
np.random.seed(seed + self.total_batches_seen)
if self.batch_index == 0:
index_array = np.arange(N)
if shuffle:
if seed is not None:
np.random.seed(seed + self.total_batches_seen)
index_array = np.random.permutation(N)
current_index = (self.batch_index * batch_size) % N
@@ -457,13 +531,28 @@ class NumpyArrayIterator(Iterator):
dim_ordering='default',
save_to_dir=None, save_prefix='', save_format='jpeg'):
if y is not None and len(X) != len(y):
raise Exception('X (images tensor) and y (labels) '
'should have the same length. '
'Found: X.shape = %s, y.shape = %s' % (np.asarray(X).shape, np.asarray(y).shape))
raise ValueError('X (images tensor) and y (labels) '
'should have the same length. '
'Found: X.shape = %s, y.shape = %s' % (np.asarray(X).shape, np.asarray(y).shape))
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
self.X = X
self.y = y
self.X = np.asarray(X)
if self.X.ndim != 4:
raise ValueError('Input data in `NumpyArrayIterator` '
'should have rank 4. You passed an array '
'with shape', self.X.shape)
channels_axis = 3 if dim_ordering == 'tf' else 1
if self.X.shape[channels_axis] not in {1, 3, 4}:
raise ValueError('NumpyArrayIterator is set to use the '
'dimension ordering convention "' + dim_ordering + '" '
'(channels on axis ' + str(channels_axis) + '), i.e. expected '
'either 1, 3 or 4 channels on axis ' + str(channels_axis) + '. '
'However, it was passed an array with shape ' + str(self.X.shape) +
' (' + str(self.X.shape[channels_axis]) + ' channels).')
if y is not None:
self.y = np.asarray(y)
else:
self.y = None
self.image_data_generator = image_data_generator
self.dim_ordering = dim_ordering
self.save_to_dir = save_to_dir
@@ -506,7 +595,8 @@ class DirectoryIterator(Iterator):
dim_ordering='default',
classes=None, class_mode='categorical',
batch_size=32, shuffle=True, seed=None,
save_to_dir=None, save_prefix='', save_format='jpeg'):
save_to_dir=None, save_prefix='', save_format='jpeg',
follow_links=False):
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
self.directory = directory
@@ -550,16 +640,20 @@ class DirectoryIterator(Iterator):
self.nb_class = len(classes)
self.class_indices = dict(zip(classes, range(len(classes))))
def _recursive_list(subpath):
return sorted(os.walk(subpath, followlinks=follow_links), key=lambda tpl: tpl[0])
for subdir in classes:
subpath = os.path.join(directory, subdir)
for fname in os.listdir(subpath):
is_valid = False
for extension in white_list_formats:
if fname.lower().endswith('.' + extension):
is_valid = True
break
if is_valid:
self.nb_sample += 1
for root, dirs, files in _recursive_list(subpath):
for fname in files:
is_valid = False
for extension in white_list_formats:
if fname.lower().endswith('.' + extension):
is_valid = True
break
if is_valid:
self.nb_sample += 1
print('Found %d images belonging to %d classes.' % (self.nb_sample, self.nb_class))
# second, build an index of the images in the different class subfolders
@@ -568,16 +662,19 @@ class DirectoryIterator(Iterator):
i = 0
for subdir in classes:
subpath = os.path.join(directory, subdir)
for fname in os.listdir(subpath):
is_valid = False
for extension in white_list_formats:
if fname.lower().endswith('.' + extension):
is_valid = True
break
if is_valid:
self.classes[i] = self.class_indices[subdir]
self.filenames.append(os.path.join(subdir, fname))
i += 1
for root, dirs, files in _recursive_list(subpath):
for fname in files:
is_valid = False
for extension in white_list_formats:
if fname.lower().endswith('.' + extension):
is_valid = True
break
if is_valid:
self.classes[i] = self.class_indices[subdir]
i += 1
# add filename relative to directory
absolute_path = os.path.join(root, fname)
self.filenames.append(os.path.relpath(absolute_path, directory))
super(DirectoryIterator, self).__init__(self.nb_sample, batch_size, shuffle, seed)
def next(self):
@@ -589,7 +686,9 @@ class DirectoryIterator(Iterator):
# build batch of image data
for i, j in enumerate(index_array):
fname = self.filenames[j]
img = load_img(os.path.join(self.directory, fname), grayscale=grayscale, target_size=self.target_size)
img = load_img(os.path.join(self.directory, fname),
grayscale=grayscale,
target_size=self.target_size)
x = img_to_array(img, dim_ordering=self.dim_ordering)
x = self.image_data_generator.random_transform(x)
x = self.image_data_generator.standardize(x)
+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)
+5 -5
Ver Arquivo
@@ -179,14 +179,14 @@ class Tokenizer(object):
if self.word_index:
nb_words = len(self.word_index) + 1
else:
raise Exception('Specify a dimension (nb_words argument), '
'or fit on some text data first.')
raise ValueError('Specify a dimension (nb_words argument), '
'or fit on some text data first.')
else:
nb_words = self.nb_words
if mode == 'tfidf' and not self.document_count:
raise Exception('Fit the Tokenizer on some data '
'before using tfidf mode.')
raise ValueError('Fit the Tokenizer on some data '
'before using tfidf mode.')
X = np.zeros((len(sequences), nb_words))
for i, seq in enumerate(sequences):
@@ -214,5 +214,5 @@ class Tokenizer(object):
idf = np.log(1 + self.document_count / (1 + self.index_docs.get(j, 0)))
X[i][j] = tf * idf
else:
raise Exception('Unknown vectorization mode: ' + str(mode))
raise ValueError('Unknown vectorization mode:', mode)
return X
+48 -83
Ver Arquivo
@@ -1,20 +1,27 @@
from __future__ import absolute_import
from . import backend as K
from .utils.generic_utils import get_from_module
import warnings
class Regularizer(object):
def set_param(self, p):
self.p = p
def set_layer(self, layer):
self.layer = layer
def __call__(self, loss):
return loss
def __call__(self, x):
return 0
def get_config(self):
return {'name': self.__class__.__name__}
def set_param(self, _):
warnings.warn('The `set_param` method on regularizers is deprecated. '
'It no longer does anything, '
'and it will be removed after 06/2017.')
def set_layer(self, _):
warnings.warn('The `set_layer` method on regularizers is deprecated. '
'It no longer does anything, '
'and it will be removed after 06/2017.')
class EigenvalueRegularizer(Regularizer):
'''This takes a constant that controls
@@ -26,61 +33,43 @@ class EigenvalueRegularizer(Regularizer):
'''
def __init__(self, k):
self.k = k
self.uses_learning_phase = True
def set_param(self, p):
self.p = p
def __call__(self, x):
if K.ndim(x) != 2:
raise ValueError('EigenvalueRegularizer '
'is only available for tensors of rank 2.')
covariance = K.dot(K.transpose(x), x)
dim1, dim2 = K.eval(K.shape(covariance))
def __call__(self, loss):
power = 9 # number of iterations of the power method
W = self.p
if K.ndim(W) > 2:
raise Exception('Eigenvalue Decay regularizer '
'is only available for dense '
'and embedding layers.')
WW = K.dot(K.transpose(W), W)
dim1, dim2 = K.eval(K.shape(WW)) # number of neurons in the layer
# power method for approximating the dominant eigenvector:
o = K.ones([dim1, 1]) # initial values for the dominant eigenvector
main_eigenvect = K.dot(WW, o)
# Power method for approximating the dominant eigenvector:
power = 9 # Number of iterations of the power method.
o = K.ones([dim1, 1]) # Initial values for the dominant eigenvector.
main_eigenvect = K.dot(covariance, o)
for n in range(power - 1):
main_eigenvect = K.dot(WW, main_eigenvect)
main_eigenvect = K.dot(covariance, main_eigenvect)
covariance_d = K.dot(covariance, main_eigenvect)
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
return K.in_train_phase(regularized_loss[0, 0], loss)
# The corresponding dominant eigenvalue:
main_eigenval = (K.dot(K.transpose(covariance_d), main_eigenvect) /
K.dot(K.transpose(main_eigenvect), main_eigenvect))
# Multiply by the given regularization gain.
regularization = (main_eigenval ** 0.5) * self.k
return K.sum(regularization)
class WeightRegularizer(Regularizer):
class L1L2Regularizer(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
def set_param(self, p):
self.p = p
def __call__(self, loss):
if not hasattr(self, 'p'):
raise Exception('Need to call `set_param` on '
'WeightRegularizer instance '
'before calling the instance. '
'Check that you are not passing '
'a WeightRegularizer instead of an '
'ActivityRegularizer '
'(i.e. activity_regularizer="l2" instead '
'of activity_regularizer="activity_l2".')
regularized_loss = loss
def __call__(self, x):
regularization = 0
if self.l1:
regularized_loss += K.sum(self.l1 * K.abs(self.p))
regularization += K.sum(self.l1 * K.abs(x))
if self.l2:
regularized_loss += K.sum(self.l2 * K.square(self.p))
return K.in_train_phase(regularized_loss, loss)
regularization += K.sum(self.l2 * K.square(x))
return regularization
def get_config(self):
return {'name': self.__class__.__name__,
@@ -88,60 +77,36 @@ class WeightRegularizer(Regularizer):
'l2': float(self.l2)}
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
# Aliases.
def set_layer(self, layer):
self.layer = layer
def __call__(self, loss):
if not hasattr(self, 'layer'):
raise Exception('Need to call `set_layer` on '
'ActivityRegularizer instance '
'before calling the instance.')
regularized_loss = loss
for i in range(len(self.layer.inbound_nodes)):
output = self.layer.get_output_at(i)
if self.l1:
regularized_loss += K.sum(self.l1 * K.abs(output))
if self.l2:
regularized_loss += K.sum(self.l2 * K.square(output))
return K.in_train_phase(regularized_loss, loss)
def get_config(self):
return {'name': self.__class__.__name__,
'l1': float(self.l1),
'l2': float(self.l2)}
WeightRegularizer = L1L2Regularizer
ActivityRegularizer = L1L2Regularizer
def l1(l=0.01):
return WeightRegularizer(l1=l)
return L1L2Regularizer(l1=l)
def l2(l=0.01):
return WeightRegularizer(l2=l)
return L1L2Regularizer(l2=l)
def l1l2(l1=0.01, l2=0.01):
return WeightRegularizer(l1=l1, l2=l2)
return L1L2Regularizer(l1=l1, l2=l2)
def activity_l1(l=0.01):
return ActivityRegularizer(l1=l)
return L1L2Regularizer(l1=l)
def activity_l2(l=0.01):
return ActivityRegularizer(l2=l)
return L1L2Regularizer(l2=l)
def activity_l1l2(l1=0.01, l2=0.01):
return ActivityRegularizer(l1=l1, l2=l2)
return L1L2Regularizer(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)
+24 -1
Ver Arquivo
@@ -40,6 +40,20 @@ else:
def get_file(fname, origin, untar=False,
md5_hash=None, cache_subdir='datasets'):
'''Downloads a file from a URL if it not already in the cache.
Passing the MD5 hash will verify the file after download as well as if it is already present in the cache.
# Arguments
fname: name of the file
origin: original URL of the file
untar: boolean, whether the file should be decompressed
md5_hash: MD5 hash of the file for verification
cache_subdir: directory being used as the cache
# Returns
Path to the downloaded file
'''
datadir_base = os.path.expanduser(os.path.join('~', '.keras'))
if not os.access(datadir_base, os.W_OK):
datadir_base = os.path.join('/tmp', '.keras')
@@ -65,7 +79,7 @@ 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
@@ -110,6 +124,15 @@ def get_file(fname, origin, untar=False,
def validate_file(fpath, md5_hash):
'''Validates a file against a MD5 hash
# Arguments
fpath: path to the file being validated
md5_hash: the MD5 hash being validated against
# Returns
Whether the file is valid
'''
hasher = hashlib.md5()
with open(fpath, 'rb') as f:
buf = f.read()
+51 -19
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,
@@ -10,22 +12,22 @@ def get_from_module(identifier, module_params, module_name,
if isinstance(identifier, six.string_types):
res = module_params.get(identifier)
if not res:
raise Exception('Invalid ' + str(module_name) + ': ' +
str(identifier))
raise ValueError('Invalid ' + str(module_name) + ': ' +
str(identifier))
if instantiate and not kwargs:
return res()
elif instantiate and kwargs:
return res(**kwargs)
else:
return res
elif type(identifier) is dict:
elif isinstance(identifier, dict):
name = identifier.pop('name')
res = module_params.get(name)
if res:
return res(**identifier)
else:
raise Exception('Invalid ' + str(module_name) + ': ' +
str(identifier))
raise ValueError('Invalid ' + str(module_name) + ': ' +
str(identifier))
return identifier
@@ -33,11 +35,38 @@ 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 globs is None:
globs = globals()
return python_types.FunctionType(code, globs,
name=code.co_name,
argdefs=defaults,
closure=closure)
class Progbar(object):
def __init__(self, target, width=30, verbose=1, interval=0.01):
'''
@param target: total number of steps expected
@param interval: minimum visual progress update interval (in seconds)
'''Dislays a progress bar.
# Arguments:
target: Total number of steps expected.
interval: Minimum visual progress update interval (in seconds).
'''
self.width = width
self.target = target
@@ -51,15 +80,18 @@ class Progbar(object):
self.verbose = verbose
def update(self, current, values=[], force=False):
'''
@param current: index of current step
@param values: list of tuples (name, value_for_last_step).
The progress bar will display averages for these values.
@param force: force visual progress update
'''Updates the progress bar.
# Arguments
current: Index of current step.
values: List of tuples (name, value_for_last_step).
The progress bar will display averages for these values.
force: Whether to force visual progress update.
'''
for k, v in values:
if k not in self.sum_values:
self.sum_values[k] = [v * (current - self.seen_so_far), current - self.seen_so_far]
self.sum_values[k] = [v * (current - self.seen_so_far),
current - self.seen_so_far]
self.unique_values.append(k)
else:
self.sum_values[k][0] += v * (current - self.seen_so_far)
@@ -72,8 +104,8 @@ class Progbar(object):
return
prev_total_width = self.total_width
sys.stdout.write("\b" * prev_total_width)
sys.stdout.write("\r")
sys.stdout.write('\b' * prev_total_width)
sys.stdout.write('\r')
numdigits = int(np.floor(np.log10(self.target))) + 1
barstr = '%%%dd/%%%dd [' % (numdigits, numdigits)
@@ -103,7 +135,7 @@ class Progbar(object):
info += ' - %ds' % (now - self.start)
for k in self.unique_values:
info += ' - %s:' % k
if type(self.sum_values[k]) is list:
if isinstance(self.sum_values[k], list):
avg = self.sum_values[k][0] / max(1, self.sum_values[k][1])
if abs(avg) > 1e-3:
info += ' %.4f' % avg
@@ -114,13 +146,13 @@ class Progbar(object):
self.total_width += len(info)
if prev_total_width > self.total_width:
info += ((prev_total_width - self.total_width) * " ")
info += ((prev_total_width - self.total_width) * ' ')
sys.stdout.write(info)
sys.stdout.flush()
if current >= self.target:
sys.stdout.write("\n")
sys.stdout.write('\n')
if self.verbose == 2:
if current >= self.target:
+31 -4
Ver Arquivo
@@ -6,9 +6,33 @@ from collections import defaultdict
class HDF5Matrix():
'''Representation of HDF5 dataset which can be used instead of a
Numpy array.
# Example
```python
X_data = HDF5Matrix('input/file.hdf5', 'data')
model.predict(X_data)
```
Providing start and end allows use of a slice of the dataset.
Optionally, a normalizer function (or lambda) can be given. This will
be called on every slice of data retrieved.
# Arguments
datapath: string, path to a HDF5 file
dataset: string, name of the HDF5 dataset in the file specified
in datapath
start: int, start of desired slice of the specified dataset
end: int, end of desired slice of the specified dataset
normalizer: function to be called on data when retrieved
'''
refs = defaultdict(int)
def __init__(self, datapath, dataset, start, end, normalizer=None):
def __init__(self, datapath, dataset, start=0, end=None, normalizer=None):
import h5py
if datapath not in list(self.refs.keys()):
@@ -16,9 +40,12 @@ class HDF5Matrix():
self.refs[datapath] = f
else:
f = self.refs[datapath]
self.start = start
self.end = end
self.data = f[dataset]
self.start = start
if end is None:
self.end = self.data.shape[0]
else:
self.end = end
self.normalizer = normalizer
def __len__(self):
@@ -59,7 +86,7 @@ def save_array(array, name):
import tables
f = tables.open_file(name, 'w')
atom = tables.Atom.from_dtype(array.dtype)
ds = f.createCArray(f.root, 'data', atom, array.shape)
ds = f.create_carray(f.root, 'data', atom, array.shape)
ds[:] = array
f.close()
+45 -11
Ver Arquivo
@@ -1,9 +1,10 @@
from __future__ import print_function
import inspect
from .generic_utils import get_from_module
from .np_utils import convert_kernel
from ..layers import *
from ..models import Model, Sequential, Graph
from ..models import Model, Sequential
from .. import backend as K
@@ -15,7 +16,7 @@ def layer_from_config(config, custom_objects={}):
of custom (non-Keras) objects to class/functions
# Returns
Layer instance (may be Model, Sequential, Graph, Layer...)
Layer instance (may be Model, Sequential, Layer...)
'''
# Insert custom layers into globals so they can
# be accessed by `get_from_module`.
@@ -26,19 +27,29 @@ def layer_from_config(config, custom_objects={}):
if class_name == 'Sequential':
layer_class = Sequential
elif class_name == 'Graph':
layer_class = Graph
elif class_name in ['Model', 'Container']:
layer_class = Model
else:
layer_class = get_from_module(class_name, globals(), 'layer',
instantiate=False)
return layer_class.from_config(config['config'])
arg_spec = inspect.getargspec(layer_class.from_config)
if 'custom_objects' in arg_spec.args:
return layer_class.from_config(config['config'], custom_objects=custom_objects)
else:
return layer_class.from_config(config['config'])
def print_summary(layers, relevant_nodes=None, line_length=100, positions=[.33, .55, .67, 1.]):
# line_length: total length of printed lines
# positions: relative or absolute positions of log elements in each line
def print_summary(layers, relevant_nodes=None,
line_length=100, positions=[.33, .55, .67, 1.]):
'''Prints a summary of a layer
# Arguments
layers: list of layers to print summaries of
relevant_nodes: list of relevant nodes
line_length: total length of printed lines
positions: relative or absolute positions of log elements in each line
'''
if positions[-1] <= 1:
positions = [int(line_length * p) for p in positions]
# header names for the different log elements
@@ -47,6 +58,8 @@ def print_summary(layers, relevant_nodes=None, line_length=100, positions=[.33,
def print_row(fields, positions):
line = ''
for i in range(len(fields)):
if i > 0:
line = line[:-1] + ' '
line += str(fields[i])
line = line[:positions[i]]
line += ' ' * (positions[i] - len(line))
@@ -87,19 +100,40 @@ def print_summary(layers, relevant_nodes=None, line_length=100, positions=[.33,
fields = ['', '', '', connections[i]]
print_row(fields, positions)
total_params = 0
for i in range(len(layers)):
print_layer_summary(layers[i])
if i == len(layers) - 1:
print('=' * line_length)
else:
print('_' * line_length)
total_params += layers[i].count_params()
print('Total params: %s' % total_params)
trainable_count, non_trainable_count = count_total_params(layers, layer_set=None)
print('Total params: {:,}'.format(trainable_count + non_trainable_count))
print('Trainable params: {:,}'.format(trainable_count))
print('Non-trainable params: {:,}'.format(non_trainable_count))
print('_' * line_length)
def count_total_params(layers, layer_set=None):
if layer_set is None:
layer_set = set()
trainable_count = 0
non_trainable_count = 0
for layer in layers:
if layer in layer_set:
continue
layer_set.add(layer)
if type(layer) in (Model, Sequential):
t, nt = count_total_params(layer.layers, layer_set)
trainable_count += t
non_trainable_count += nt
else:
trainable_count += sum([K.count_params(p) for p in layer.trainable_weights])
non_trainable_count += sum([K.count_params(p) for p in layer.non_trainable_weights])
return trainable_count, non_trainable_count
def convert_all_kernels_in_model(model):
# Note: SeparableConvolution not included
# since only supported by TF.
+21 -7
Ver Arquivo
@@ -3,12 +3,20 @@ import numpy as np
import scipy as sp
from six.moves import range
from six.moves import zip
from .. import backend as K
def to_categorical(y, nb_classes=None):
'''Convert class vector (integers from 0 to nb_classes)
to binary class matrix, for use with categorical_crossentropy.
'''Convert class vector (integers from 0 to nb_classes) to binary class matrix, for use with categorical_crossentropy.
# Arguments
y: class vector to be converted into a matrix
nb_classes: total number of classes
# Returns
A binary matrix representation of the input.
'''
y = np.array(y, dtype='int')
if not nb_classes:
nb_classes = np.max(y)+1
Y = np.zeros((len(y), nb_classes))
@@ -52,12 +60,14 @@ def categorical_probas_to_classes(p):
return np.argmax(p, axis=1)
def convert_kernel(kernel, dim_ordering='th'):
def convert_kernel(kernel, dim_ordering='default'):
'''Converts a kernel matrix (Numpy array)
from Theano format to TensorFlow format
(or reciprocally, since the transformation
is its own inverse).
'''
if dim_ordering == 'default':
dim_ordering = K.image_dim_ordering()
new_kernel = np.copy(kernel)
if kernel.ndim == 4:
# conv 2d
@@ -76,7 +86,7 @@ def convert_kernel(kernel, dim_ordering='th'):
for j in range(h):
new_kernel[i, j, :, :] = kernel[w - i - 1, h - j - 1, :, :]
else:
raise Exception('Invalid dim_ordering: ' + str(dim_ordering))
raise ValueError('Invalid dim_ordering:', dim_ordering)
elif kernel.ndim == 5:
# conv 3d
# TH kernel shape: (out_depth, input_depth, kernel_dim1, kernel_dim2, kernel_dim3)
@@ -104,7 +114,7 @@ def convert_kernel(kernel, dim_ordering='th'):
z - k - 1,
:, :]
else:
raise Exception('Invalid dim_ordering: ' + str(dim_ordering))
raise ValueError('Invalid dim_ordering:', dim_ordering)
else:
raise ValueError('Invalid kernel shape:', kernel.shape)
return new_kernel
@@ -113,21 +123,25 @@ def convert_kernel(kernel, dim_ordering='th'):
def conv_output_length(input_length, filter_size, border_mode, stride, dilation=1):
if input_length is None:
return None
assert border_mode in {'same', 'valid'}
assert border_mode in {'same', 'valid', 'full'}
dilated_filter_size = filter_size + (filter_size - 1) * (dilation - 1)
if border_mode == 'same':
output_length = input_length
elif border_mode == 'valid':
output_length = input_length - dilated_filter_size + 1
elif border_mode == 'full':
output_length = input_length + dilated_filter_size - 1
return (output_length + stride - 1) // stride
def conv_input_length(output_length, filter_size, border_mode, stride):
if output_length is None:
return None
assert border_mode in {'same', 'valid'}
assert border_mode in {'same', 'valid', 'full'}
if border_mode == 'same':
pad = filter_size // 2
elif border_mode == 'valid':
pad = 0
elif border_mode == 'full':
pad = filter_size - 1
return (output_length - 1) * stride - 2 * pad + filter_size
+16 -5
Ver Arquivo
@@ -1,7 +1,7 @@
import numpy as np
from numpy.testing import assert_allclose
import inspect
import functools
import six
from ..engine import Model, Input
from ..models import Sequential, model_from_json
@@ -45,7 +45,12 @@ def layer_test(layer_cls, kwargs={}, input_shape=None, input_dtype=None,
assert input_shape
if not input_dtype:
input_dtype = K.floatx()
input_data = (10 * np.random.random(input_shape)).astype(input_dtype)
input_data_shape = list(input_shape)
for i, e in enumerate(input_data_shape):
if e is None:
input_data_shape[i] = np.random.randint(1, 4)
input_data = (10 * np.random.random(input_data_shape))
input_data = input_data.astype(input_dtype)
elif input_shape is None:
input_shape = input_data.shape
@@ -78,7 +83,10 @@ def layer_test(layer_cls, kwargs={}, input_shape=None, input_dtype=None,
expected_output_shape = layer.get_output_shape_for(input_shape)
actual_output = model.predict(input_data)
actual_output_shape = actual_output.shape
assert expected_output_shape == actual_output_shape
for expected_dim, actual_dim in zip(expected_output_shape,
actual_output_shape):
if expected_dim is not None:
assert expected_dim == actual_dim
if expected_output is not None:
assert_allclose(actual_output, expected_output, rtol=1e-3)
@@ -97,7 +105,10 @@ def layer_test(layer_cls, kwargs={}, input_shape=None, input_dtype=None,
model.compile('rmsprop', 'mse')
actual_output = model.predict(input_data)
actual_output_shape = actual_output.shape
assert expected_output_shape == actual_output_shape
for expected_dim, actual_dim in zip(expected_output_shape,
actual_output_shape):
if expected_dim is not None:
assert expected_dim == actual_dim
if expected_output is not None:
assert_allclose(actual_output, expected_output, rtol=1e-3)
@@ -112,7 +123,7 @@ def layer_test(layer_cls, kwargs={}, input_shape=None, input_dtype=None,
def keras_test(func):
'''Clean up after tensorflow tests.
'''
@functools.wraps(func)
@six.wraps(func)
def wrapper(*args, **kwargs):
output = func(*args, **kwargs)
if K._BACKEND == 'tensorflow':
+29 -11
Ver Arquivo
@@ -1,3 +1,8 @@
import os
from ..layers.wrappers import Wrapper
from ..models import Sequential
try:
# pydot-ng is a fork of pydot that is better maintained
import pydot_ng as pydot
@@ -15,23 +20,32 @@ def model_to_dot(model, show_shapes=False, show_layer_names=True):
dot.set('concentrate', True)
dot.set_node_defaults(shape='record')
if model.__class__.__name__ == 'Sequential':
if isinstance(model, Sequential):
if not model.built:
model.build()
model = model.model
layers = model.layers
# first, populate the nodes of the graph
# Create graph nodes.
for layer in layers:
layer_id = str(id(layer))
if show_layer_names:
label = str(layer.name) + ' (' + layer.__class__.__name__ + ')'
else:
label = layer.__class__.__name__
# Append a wrapped layer's label to node's label, if it exists.
layer_name = layer.name
class_name = layer.__class__.__name__
if isinstance(layer, Wrapper):
layer_name = '{}({})'.format(layer_name, layer.layer.name)
child_class_name = layer.layer.__class__.__name__
class_name = '{}({})'.format(class_name, child_class_name)
# Create node's label.
if show_layer_names:
label = '{}: {}'.format(layer_name, class_name)
else:
label = class_name
# Rebuild the label as a table including input/output shapes.
if show_shapes:
# Build the label that will actually contain a table with the
# input/output
try:
outputlabels = str(layer.output_shape)
except:
@@ -48,13 +62,12 @@ def model_to_dot(model, show_shapes=False, show_layer_names=True):
node = pydot.Node(layer_id, label=label)
dot.add_node(node)
# second, add the edges
# Connect nodes with edges.
for layer in layers:
layer_id = str(id(layer))
for i, node in enumerate(layer.inbound_nodes):
node_key = layer.name + '_ib-' + str(i)
if node_key in model.container_nodes:
# add edges
for inbound_layer in node.inbound_layers:
inbound_layer_id = str(id(inbound_layer))
layer_id = str(id(layer))
@@ -64,4 +77,9 @@ def model_to_dot(model, show_shapes=False, show_layer_names=True):
def plot(model, to_file='model.png', show_shapes=False, show_layer_names=True):
dot = model_to_dot(model, show_shapes, show_layer_names)
dot.write_png(to_file)
_, format = os.path.splitext(to_file)
if not format:
format = 'png'
else:
format = format[1:]
dot.write(to_file, format=format)
+7 -7
Ver Arquivo
@@ -66,7 +66,7 @@ class BaseWrapper(object):
Sequential.predict_classes, Sequential.evaluate]
if self.build_fn is None:
legal_params_fns.append(self.__call__)
elif not isinstance(self.build_fn, types.FunctionType):
elif not isinstance(self.build_fn, types.FunctionType) and not isinstance(self.build_fn, types.MethodType):
legal_params_fns.append(self.build_fn.__call__)
else:
legal_params_fns.append(self.build_fn)
@@ -130,7 +130,7 @@ class BaseWrapper(object):
if self.build_fn is None:
self.model = self.__call__(**self.filter_sk_params(self.__call__))
elif not isinstance(self.build_fn, types.FunctionType):
elif not isinstance(self.build_fn, types.FunctionType) and not isinstance(self.build_fn, types.MethodType):
self.model = self.build_fn(
**self.filter_sk_params(self.build_fn.__call__))
else:
@@ -242,14 +242,14 @@ class KerasClassifier(BaseWrapper):
y = to_categorical(y)
outputs = self.model.evaluate(X, y, **kwargs)
if type(outputs) is not list:
if not isinstance(outputs, list):
outputs = [outputs]
for name, output in zip(self.model.metrics_names, outputs):
if name == 'acc':
return output
raise Exception('The model is not configured to compute accuracy. '
'You should pass `metrics=["accuracy"]` to '
'the `model.compile()` method.')
raise ValueError('The model is not configured to compute accuracy. '
'You should pass `metrics=["accuracy"]` to '
'the `model.compile()` method.')
class KerasRegressor(BaseWrapper):
@@ -290,6 +290,6 @@ class KerasRegressor(BaseWrapper):
'''
kwargs = self.filter_sk_params(Sequential.evaluate, kwargs)
loss = self.model.evaluate(X, y, **kwargs)
if type(loss) is list:
if isinstance(loss, list):
return loss[0]
return loss
-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='1.2.0',
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/1.2.0',
license='MIT',
install_requires=['theano', 'pyyaml', 'six'],
extras_require={

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