pytorch-dnc
Sample on-line plotting while training(avg loss)/testing(write/read weights & memory) NTM on the copy task (top 2 rows, 1st row converges to sequentially write to lower locations, 2nd row converges to sequentially write to upper locations) and DNC on the repeat-copy task (3rd row) (the write/read weights here are after location focus so are no longer necessarily normalized within each head by design):
Sample loggings while training DNC on the repeat-copy task (we use WARNING
as the logging level currently to get rid of the INFO
printouts from visdom):
[WARNING ] (MainProcess) <===================================>[WARNING ] (MainProcess) bash$: python -m visdom.server [WARNING ] (MainProcess) http://localhost:8097/env/daim_17051000 [WARNING ] (MainProcess) <===================================> Agent: [WARNING ] (MainProcess) <-----------------------------======> Env: [WARNING ] (MainProcess) Creating {repeat-copy | } w/ Seed: 123 [WARNING ] (MainProcess) Word {length}: {4} [WARNING ] (MainProcess) Words # {min, max}: {1, 2}[WARNING ] (MainProcess) Repeats {min, max}: {1, 2} [WARNING ] (MainProcess) <-----------------------------======> Circuit: {Controller, Accessor} [WARNING ] (MainProcess) <--------------------------------===> Controller: [WARNING ] (MainProcess) LSTMController ( (in_2_hid): LSTMCell(70, 64, bias=1) ) [WARNING ] (MainProcess) <--------------------------------===> Accessor: {WriteHead, ReadHead, Memory} [WARNING ] (MainProcess) <-----------------------------------> WriteHeads: {1 heads} [WARNING ] (MainProcess) DynamicWriteHead ( (hid_2_key): Linear (64 -> 16) (hid_2_beta): Linear (64 -> 1) (hid_2_alloc_gate): Linear (64 -> 1) (hid_2_write_gate): Linear (64 -> 1) (hid_2_erase): Linear (64 -> 16) (hid_2_add): Linear (64 -> 16) ) [WARNING ] (MainProcess) <-----------------------------------> ReadHeads: {4 heads} [WARNING ] (MainProcess) DynamicReadHead ( (hid_2_key): Linear (64 -> 64) (hid_2_beta): Linear (64 -> 4) (hid_2_free_gate): Linear (64 -> 4) (hid_2_read_mode): Linear (64 -> 12) ) [WARNING ] (MainProcess) <-----------------------------------> Memory: {16(batch_size) x 16(mem_hei) x 16(mem_wid)} [WARNING ] (MainProcess) <-----------------------------======> Circuit: {Overall Architecture} [WARNING ] (MainProcess) DNCCircuit ( (controller): LSTMController ( (in_2_hid): LSTMCell(70, 64, bias=1) ) (accessor): DynamicAccessor ( (write_heads): DynamicWriteHead ( (hid_2_key): Linear (64 -> 16) (hid_2_beta): Linear (64 -> 1) (hid_2_alloc_gate): Linear (64 -> 1) (hid_2_write_gate): Linear (64 -> 1) (hid_2_erase): Linear (64 -> 16) (hid_2_add): Linear (64 -> 16) ) (read_heads): DynamicReadHead ( (hid_2_key): Linear (64 -> 64) (hid_2_beta): Linear (64 -> 4) (hid_2_free_gate): Linear (64 -> 4) (hid_2_read_mode): Linear (64 -> 12) ) ) (hid_to_out): Linear (128 -> 5) ) [WARNING ] (MainProcess) No Pretrained Model. Will Train From Scratch. [WARNING ] (MainProcess) <===================================> Training ... [WARNING ] (MainProcess) Reporting @ Step: 500 | Elapsed Time: 30.609361887 [WARNING ] (MainProcess) Training Stats: avg_loss: 0.014866309287 [WARNING ] (MainProcess) Evaluating @ Step: 500 [WARNING ] (MainProcess) Evaluation Took: 1.6457400322 [WARNING ] (MainProcess) Iteration: 500; loss_avg: 0.0140423600748 [WARNING ] (MainProcess) Saving Model @ Step: 500: /home/zhang/ws/17_ws/pytorch-dnc/models/daim_17051000.pth ... [WARNING ] (MainProcess) Saved Model @ Step: 500: /home/zhang/ws/17_ws/pytorch-dnc/models/daim_17051000.pth. [WARNING ] (MainProcess) Resume Training @ Step: 500 ...
This repo currently contains the following algorithms:
Tasks:
copy
repeat-copy
NOTE: we follow the exact code structure as pytorch-rl so as to make the code easily transplantable.
./utils/factory.py
We suggest the users refer to
./utils/factory.py
, where we list all the integratedEnv
,Circuit
,Agent
intoDict
's. All of the core classes are implemented in./core/
. The factory pattern in./utils/factory.py
makes the code super clean, as no matter what type ofCircuit
you want to train, or which type ofEnv
you want to train on, all you need to do is to simply modify some parameters in./utils/options.py
, then the./main.py
will do it all (NOTE: this./main.py
file never needs to be modified).
namings
To make the code more clean and readable, we name the variables using the following pattern:
*_vb
:torch.autograd.Variable
's or a list of such objects
*_ts
:torch.Tensor
's or a list of such objectsotherwise: normal python datatypes
Python 2.7
You only need to modify some parameters in ./utils/options.py
to train a new configuration.
Configure your training in ./utils/options.py
:
line 12
: add an entry intoCONFIGS
to define your training (agent_type
,env_type
,game
,circuit_type
)
line 28
: choose the entry you just added
line 24-25
: fill in your machine/cluster ID (MACHINE
) and timestamp (TIMESTAMP
) to define your training signature (MACHINE_TIMESTAMP
), the corresponding model file and the log file of this training will be saved under this signature (./models/MACHINE_TIMESTAMP.pth
&./logs/MACHINE_TIMESTAMP.log
respectively). Also the visdom visualization will be displayed under this signature (first activate the visdom server by type in bash:python -m visdom.server &
, then open this address in your browser:http://localhost:8097/env/MACHINE_TIMESTAMP
)
line 28
: to train a model, setmode=1
(training visualization will be underhttp://localhost:8097/env/MACHINE_TIMESTAMP
); to test the model of this current training, all you need to do is to setmode=2
(testing visualization will be underhttp://localhost:8097/env/MACHINE_TIMESTAMP_test
).
Run:
python main.py
The difference between NTM
& DNC
is stated as follows in the DNC
[2] paper:
Comparison with the neural Turing machine. The neural Turing machine (NTM) was the predecessor to the DNC described in this work. It used a similar architecture of neural network controller with read–write access to a memory matrix, but differed in the access mechanism used to interface with the memory. In the NTM, content-based addressing was combined with location-based addressing to allow the network to iterate through memory locations in order of their indices (for example, location n followed by n+1 and so on). This allowed the network to store and retrieve temporal sequences in contiguous blocks of memory. However, there were several drawbacks. First, the NTM has no mechanism to ensure that blocks of allocated memory do not overlap and interfere—a basic problem of computer memory management. Interference is not an issue for the dynamic memory allocation used by DNCs, which provides single free locations at a time, irrespective of index, and therefore does not require contiguous blocks. Second, the NTM has no way of freeing locations that have already been written to and, hence, no way of reusing memory when processing long sequences. This problem is addressed in DNCs by the free gates used for de-allocation. Third, sequential information is preserved only as long as the NTM continues to iterate through consecutive locations; as soon as the write head jumps to a different part of the memory (using content-based addressing) the order of writes before and after the jump cannot be recovered by the read head. The temporal link matrix used by DNCs does not suffer from this problem because it tracks the order in which writes were made.
We thus make some effort to put those two together in a combined codebase. The classes implemented have the following hierarchy:
Agent
Controller
Accessor
WriteHead
ReadHead
Memory
Env
Circuit
The part where NTM
& DNC
differs is the Accessor
, where in the code NTM
uses the StaticAccessor
(may not be an appropriate name but we use this to make the code more consistent) and DNC
uses the DynamicAccessor
. Both Accessor
classes use _content_focus()
and _location_focus()
(may not be an appropriate name for DNC
but we use this to make the code more consistent). The _content_focus()
is the same for both classes, but the _location_focus()
for DNC
is much more complicated as it uses dynamic allocation
additionally for write and temporal link
additionally for read. Those focus (or attention) mechanisms are implemented in Head
classes, and those focuses output a weight
vector for each head
(write/read). Those weight
vectors are then used in _access()
to interact with the external memory
.
The sturcture for Env
might look strange as this class was originally designed for reinforcement learning
settings as in pytorch-rl; here we use it for providing datasets for supervised learning
, so the reward
, action
and terminal
are always left blank in this repo.
Neural SLAM: We present an approach for agents to learn representations of a global map from sensor data, to aid their exploration in new environments. To achieve this, we embed procedures mimicking that of traditional Simultaneous Localization and Mapping (SLAM) into the soft attention based addressing of external memory architectures, in which the external memory acts as an internal representation of the environment. This structure encourages the evolution of SLAM-like behaviors inside a completely differentiable deep neural network. We show that this approach can help reinforcement learning agents to successfully explore new environments where long-term memory is essential. We validate our approach in both challenging grid-world environments and preliminary Gazebo experiments. A video of our experiments can be found at: url{https://goo.gl/RfiSxo}.
@article{zhang2017neural, title={Neural SLAM}, author={Zhang, Jingwei and Tai, Lei and Boedecker, Joschka and Burgard, Wolfram and Liu, Ming}, journal={arXiv preprint arXiv:1706.09520}, year={2017} }
If you find this library useful and would like to cite it, the following would be appropriate:
@misc{pytorch-dnc, author = {Zhang, Jingwei}, title = {jingweiz/pytorch-dnc}, url = {https://github.com/jingweiz/pytorch-dnc}, year = {2017} }
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