Repository: keon/pointer-networks
Branch: master
Commit: bca17beee594
Files: 9
Total size: 11.9 KB
Directory structure:
gitextract_f0mounp3/
├── .gitignore
├── LICENSE
├── PointerLSTM.py
├── README.md
├── model_weight_100.hdf5
├── requirement.txt
├── run.py
├── sort_data.py
└── tsp_data.py
================================================
FILE CONTENTS
================================================
================================================
FILE: .gitignore
================================================
# Byte-compiled / optimized / DLL files
__pycache__/
*.py[cod]
*$py.class
# C extensions
*.so
# Distribution / packaging
.Python
env/
build/
develop-eggs/
dist/
downloads/
eggs/
.eggs/
lib/
lib64/
parts/
sdist/
var/
*.egg-info/
.installed.cfg
*.egg
# PyInstaller
# Usually these files are written by a python script from a template
# before PyInstaller builds the exe, so as to inject date/other infos into it.
*.manifest
*.spec
# Installer logs
pip-log.txt
pip-delete-this-directory.txt
# Unit test / coverage reports
htmlcov/
.tox/
.coverage
.coverage.*
.cache
nosetests.xml
coverage.xml
*,cover
.hypothesis/
# Translations
*.mo
*.pot
# Django stuff:
*.log
local_settings.py
# Flask stuff:
instance/
.webassets-cache
# Scrapy stuff:
.scrapy
# Sphinx documentation
docs/_build/
# PyBuilder
target/
# IPython Notebook
.ipynb_checkpoints
# pyenv
.python-version
# celery beat schedule file
celerybeat-schedule
# dotenv
.env
# virtualenv
venv/
ENV/
# Spyder project settings
.spyderproject
# Rope project settings
.ropeproject
================================================
FILE: LICENSE
================================================
MIT License
Copyright (c) 2017 Keon Kim
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.
================================================
FILE: PointerLSTM.py
================================================
import keras.backend as K
from keras.activations import tanh, softmax
from keras.engine import InputSpec
from keras.layers import LSTM
import keras
class Attention(keras.layers.Layer):
"""
Attention layer
"""
def __init__(self, hidden_dimensions, name='attention'):
super(Attention, self).__init__(name=name, trainable=True)
self.W1 = keras.layers.Dense(hidden_dimensions, use_bias=False)
self.W2 = keras.layers.Dense(hidden_dimensions, use_bias=False)
self.V = keras.layers.Dense(1, use_bias=False)
def call(self, encoder_outputs, dec_output, mask=None):
w1_e = self.W1(encoder_outputs)
w2_d = self.W2(dec_output)
tanh_output = tanh(w1_e + w2_d)
v_dot_tanh = self.V(tanh_output)
if mask is not None:
v_dot_tanh += (mask * -1e9)
attention_weights = softmax(v_dot_tanh, axis=1)
att_shape = K.shape(attention_weights)
return K.reshape(attention_weights, (att_shape[0], att_shape[1]))
class Decoder(keras.layers.Layer):
"""
Decoder class for PointerLayer
"""
def __init__(self, hidden_dimensions):
super(Decoder, self).__init__()
self.lstm = keras.layers.LSTM(
hidden_dimensions, return_sequences=False, return_state=True)
def call(self, x, hidden_states):
dec_output, state_h, state_c = self.lstm(
x, initial_state=hidden_states)
return dec_output, [state_h, state_c]
def get_initial_state(self, inputs):
return self.lstm.get_initial_state(inputs)
def process_inputs(self, x_input, initial_states, constants):
return self.lstm._process_inputs(x_input, initial_states, constants)
class PointerLSTM(keras.layers.Layer):
"""
PointerLSTM
"""
def __init__(self, hidden_dimensions, name='pointer', **kwargs):
super(PointerLSTM, self).__init__(
hidden_dimensions, name=name, **kwargs)
self.hidden_dimensions = hidden_dimensions
self.attention = Attention(hidden_dimensions)
self.decoder = Decoder(hidden_dimensions)
def build(self, input_shape):
super(PointerLSTM, self).build(input_shape)
self.input_spec = [InputSpec(shape=input_shape)]
def call(self, x, training=None, mask=None, states=None):
"""
:param Tensor x: Should be the output of the decoder
:param Tensor states: last state of the decoder
:param Tensor mask: The mask to apply
:return: Pointers probabilities
"""
input_shape = self.input_spec[0].shape
en_seq = x
x_input = x[:, input_shape[1] - 1, :]
x_input = K.repeat(x_input, input_shape[1])
if states:
initial_states = states
else:
initial_states = self.decoder.get_initial_state(x_input)
constants = []
preprocessed_input, _, constants = self.decoder.process_inputs(
x_input, initial_states, constants)
constants.append(en_seq)
last_output, outputs, states = K.rnn(self.step, preprocessed_input,
initial_states,
go_backwards=self.decoder.lstm.go_backwards,
constants=constants,
input_length=input_shape[1])
return outputs
def step(self, x_input, states):
x_input = K.expand_dims(x_input,1)
input_shape = self.input_spec[0].shape
en_seq = states[-1]
_, [h, c] = self.decoder(x_input, states[:-1])
dec_seq = K.repeat(h, input_shape[1])
probs = self.attention(dec_seq, en_seq)
return probs, [h, c]
def get_output_shape_for(self, input_shape):
# output shape is not affected by the attention component
return (input_shape[0], input_shape[1], input_shape[1])
def compute_output_shape(self, input_shape):
return (input_shape[0], input_shape[1], input_shape[1])
================================================
FILE: README.md
================================================
## Code upgrade of [Pointer Networks](http://arxiv.org/pdf/1511.06391v4.pdf) to run on keras>=2.4.3 and tensorflow>=2.2.0
The original author code is at https://github.com/keon/pointer-networks.git.
================================================
FILE: requirement.txt
================================================
keras==2.4.3
tensorflow==2.2.0
================================================
FILE: run.py
================================================
from keras.models import Model
from keras.layers import LSTM, Input
from keras.callbacks import LearningRateScheduler
from keras.utils.np_utils import to_categorical
from pointer import PointerLSTM
import pickle
import tsp_data as tsp
import numpy as np
import keras
def scheduler(epoch):
if epoch < nb_epochs/4:
return learning_rate
elif epoch < nb_epochs/2:
return learning_rate*0.5
return learning_rate*0.1
print("preparing dataset...")
t = tsp.Tsp()
X, Y = t.next_batch(10000)
x_test, y_test = t.next_batch(1000)
YY = []
for y in Y:
YY.append(to_categorical(y))
YY = np.asarray(YY)
hidden_size = 128
seq_len = 10
nb_epochs = 10000
learning_rate = 0.1
print("building model...")
main_input = Input(shape=(seq_len, 2), name='main_input')
encoder,state_h, state_c = LSTM(hidden_size,return_sequences = True, name="encoder",return_state=True)(main_input)
decoder = PointerLSTM(hidden_size, name="decoder")(encoder,states=[state_h, state_c])
model = Model(main_input, decoder)
print(model.summary())
model.compile(optimizer='adam',
loss='categorical_crossentropy',
metrics=['accuracy'])
model.fit(X, YY, epochs=nb_epochs, batch_size=64,)
print(model.predict(x_test))
print('evaluate : ',model.evaluate(x_test,to_categorical(y_test)))
print("------")
print(to_categorical(y_test))
model.save_weights('model_weight_100.hdf5')
================================================
FILE: sort_data.py
================================================
from __future__ import absolute_import, division, print_function
import numpy as np
class DataGenerator(object):
def next_batch(self, batch_size, N, train_mode=True):
"""Return the next `batch_size` examples from this data set."""
# A sequence of random numbers from [0, 1]
encoder_batch = []
# Sorted sequence that we feed to encoder
# In inference we feed an unordered sequence again
decoder_batch = []
# Ordered sequence where one hot vector encodes
# position in the input array
target_batch = []
for _ in range(batch_size):
encoder_batch.append(np.zeros([N, 1]))
for _ in range(batch_size):
decoder_batch.append(np.zeros([N, 1]))
target_batch.append(np.zeros([N, N]))
encoder_batch = np.asarray(encoder_batch)
decoder_batch = np.asarray(decoder_batch)
target_batch = np.asarray(target_batch)
for b in range(batch_size):
shuffle = np.random.permutation(N)
sequence = np.sort(np.random.random(N))
shuffled_sequence = sequence[shuffle]
for i in range(N):
encoder_batch[b][i] = shuffled_sequence[i]
if train_mode:
decoder_batch[b][i] = sequence[i]
else:
decoder_batch[b][i] = shuffled_sequence[i]
target_batch[b, i][shuffle[i]] = 1.0
# Points to the stop symbol
# target_batch[b, N][0] = 1.0
return encoder_batch, decoder_batch, target_batch
if __name__ == "__main__":
seq_len = 3
batch_size = 3
dataset = DataGenerator()
enc_input, dec_input, targets = dataset.next_batch(batch_size, seq_len)
print("batch_size", batch_size, "seq_len", seq_len)
print("-------------encoder input-------------")
print(enc_input.shape)
print(enc_input)
print("-------------decoder input-------------")
print(dec_input.shape)
print(dec_input)
print("------------- targets -------------")
print(targets.shape)
print(targets)
================================================
FILE: tsp_data.py
================================================
import math
import numpy as np
import random
import itertools
class Tsp:
def next_batch(self, batch_size=1):
X, Y = [], []
for b in range(batch_size):
print("preparing dataset... %s/%s" % (b, batch_size))
points = self.generate_data()
solved = self.solve_tsp_dynamic(points)
X.append(points), Y.append(solved)
return np.asarray(X), np.asarray(Y)
def length(self, x, y):
return (math.sqrt((x[0]-y[0])**2 + (x[1]-y[1])**2))
def solve_tsp_dynamic(self, points):
# calc all lengths
all_distances = [[self.length(x, y) for y in points] for x in points]
# initial value - just distance from 0 to
# every other point + keep the track of edges
A = {(frozenset([0, idx+1]), idx+1): (dist, [0, idx+1])
for idx, dist in enumerate(all_distances[0][1:])}
cnt = len(points)
for m in range(2, cnt):
B = {}
for S in [frozenset(C) | {0}
for C in itertools.combinations(range(1, cnt), m)]:
for j in S - {0}:
B[(S, j)] = min([(A[(S-{j}, k)][0] + all_distances[k][j],
A[(S-{j}, k)][1] + [j])
for k in S if k != 0 and k != j])
A = B
res = min([(A[d][0] + all_distances[0][d[1]], A[d][1])
for d in iter(A)])
return res[1]
def generate_data(self, N=10):
radius = 1
rangeX = (0, 10)
rangeY = (0, 10)
qty = N
deltas = set()
for x in range(-radius, radius+1):
for y in range(-radius, radius+1):
if x*x + y*y <= radius*radius:
deltas.add((x, y))
randPoints = []
excluded = set()
i = 0
while i < qty:
x = random.randrange(*rangeX)
y = random.randrange(*rangeY)
if (x, y) in excluded:
continue
randPoints.append((x, y))
i += 1
excluded.update((x+dx, y+dy) for (dx, dy) in deltas)
return randPoints
if __name__ == "__main__":
p = Tsp()
X, Y = p.next_batch(1)
print(X)
print(Y)
gitextract_f0mounp3/ ├── .gitignore ├── LICENSE ├── PointerLSTM.py ├── README.md ├── model_weight_100.hdf5 ├── requirement.txt ├── run.py ├── sort_data.py └── tsp_data.py
SYMBOL INDEX (23 symbols across 4 files)
FILE: PointerLSTM.py
class Attention (line 8) | class Attention(keras.layers.Layer):
method __init__ (line 13) | def __init__(self, hidden_dimensions, name='attention'):
method call (line 19) | def call(self, encoder_outputs, dec_output, mask=None):
class Decoder (line 32) | class Decoder(keras.layers.Layer):
method __init__ (line 37) | def __init__(self, hidden_dimensions):
method call (line 42) | def call(self, x, hidden_states):
method get_initial_state (line 47) | def get_initial_state(self, inputs):
method process_inputs (line 50) | def process_inputs(self, x_input, initial_states, constants):
class PointerLSTM (line 54) | class PointerLSTM(keras.layers.Layer):
method __init__ (line 59) | def __init__(self, hidden_dimensions, name='pointer', **kwargs):
method build (line 66) | def build(self, input_shape):
method call (line 70) | def call(self, x, training=None, mask=None, states=None):
method step (line 99) | def step(self, x_input, states):
method get_output_shape_for (line 108) | def get_output_shape_for(self, input_shape):
method compute_output_shape (line 112) | def compute_output_shape(self, input_shape):
FILE: run.py
function scheduler (line 12) | def scheduler(epoch):
FILE: sort_data.py
class DataGenerator (line 5) | class DataGenerator(object):
method next_batch (line 6) | def next_batch(self, batch_size, N, train_mode=True):
FILE: tsp_data.py
class Tsp (line 7) | class Tsp:
method next_batch (line 8) | def next_batch(self, batch_size=1):
method length (line 17) | def length(self, x, y):
method solve_tsp_dynamic (line 20) | def solve_tsp_dynamic(self, points):
method generate_data (line 41) | def generate_data(self, N=10):
Condensed preview — 9 files, each showing path, character count, and a content snippet. Download the .json file or copy for the full structured content (13K chars).
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"path": "LICENSE",
"chars": 1065,
"preview": "MIT License\n\nCopyright (c) 2017 Keon Kim\n\nPermission is hereby granted, free of charge, to any person obtaining a copy\no"
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"preview": "## Code upgrade of [Pointer Networks](http://arxiv.org/pdf/1511.06391v4.pdf) to run on keras>=2.4.3 and tensorflow>=2.2."
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]
// ... and 1 more files (download for full content)
About this extraction
This page contains the full source code of the keon/pointer-networks GitHub repository, extracted and formatted as plain text for AI agents and large language models (LLMs). The extraction includes 9 files (11.9 KB), approximately 3.1k tokens, and a symbol index with 23 extracted functions, classes, methods, constants, and types. Use this with OpenClaw, Claude, ChatGPT, Cursor, Windsurf, or any other AI tool that accepts text input. You can copy the full output to your clipboard or download it as a .txt file.
Extracted by GitExtract — free GitHub repo to text converter for AI. Built by Nikandr Surkov.