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# Design: Sequence Decoder Generating LoDTensors
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In tasks such as machine translation and visual captioning,
a [sequence decoder](https://github.com/PaddlePaddle/book/blob/develop/08.machine_translation/README.md) is necessary to generate sequences, one word at a time.
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This documentation describes how to implement the sequence decoder as an operator.

## Beam Search based Decoder
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The [beam search algorithm](https://en.wikipedia.org/wiki/Beam_search) is necessary when generating sequences. It is a heuristic search algorithm that explores the paths by expanding the most promising node in a limited set.
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In the old version of PaddlePaddle, the C++ class `RecurrentGradientMachine` implements the general sequence decoder based on beam search, due to the complexity involved, the implementation relies on a lot of special data structures that are quite trivial and hard to be customized by users.
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There are a lot of heuristic tricks in the sequence generation tasks, so the flexibility of sequence decoder is very important to users.
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During the refactoring of PaddlePaddle, some new concepts are proposed such as:  [LoDTensor](https://github.com/PaddlePaddle/Paddle/blob/develop/paddle/framework/lod_tensor.md) and [TensorArray](https://github.com/PaddlePaddle/Paddle/blob/develop/doc/design/tensor_array.md) that can better support the sequence usage, and they can also help make the implementation of beam search based sequence decoder **more transparent and modular** .
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For example, the RNN states, candidates IDs and probabilities of beam search can be represented all as `LoDTensors`;
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the selected candidate's IDs in each time step can be stored in a `TensorArray`, and `Packed` to the sentences translated.

## Changing LoD's absolute offset to relative offsets
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The current `LoDTensor` is designed to store levels of variable-length sequences. It stores several arrays of integers where each represents a level.
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The integers in each level represent the begin and end (not inclusive) offset of a sequence **in the underlying tensor**,
let's call this format the **absolute-offset LoD** for clarity.
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The relative-offset LoD can retrieve any sequence very quickly but fails to represent empty sequences, for example, a two-level LoD is as follows
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```python
[[0, 3, 9]
 [0, 2, 3, 3, 3, 9]]
```
The first level tells that there are two sequences:
- the first's offset is `[0, 3)`
- the second's offset is `[3, 9)`

while on the second level, there are several empty sequences that both begin and end at `3`.
It is impossible to tell how many empty second-level sequences exist in the first-level sequences.

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There are many scenarios that rely on empty sequence representation, for example in machine translation or visual captioning, one instance has no translation or the empty candidate set for a prefix.
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So let's introduce another format of LoD,
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it stores **the offsets of the lower level sequences** and is called **relative-offset** LoD.

For example, to represent the same sequences of the above data

```python
[[0, 3, 6]
 [0, 2, 3, 3, 3, 9]]
```

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the first level represents that there are two sequences,
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their offsets in the second-level LoD is `[0, 3)` and `[3, 5)`.

The second level is the same with the relative offset example because the lower level is a tensor.
It is easy to find out the second sequence in the first-level LoD has two empty sequences.

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The following examples are based on relative-offset LoD.
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## Usage in a simple machine translation model
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Let's start from a simple machine translation model that is simplified from the [machine translation chapter](https://github.com/PaddlePaddle/book/tree/develop/08.machine_translation) to draw a blueprint of what a sequence decoder can do and how to use it.
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The model has an encoder that learns the semantic vector from a sequence, and a decoder which uses the sequence encoder to generate new sentences.
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**Encoder**
```python
import paddle as pd

dict_size = 8000
source_dict_size = dict_size
target_dict_size = dict_size
word_vector_dim = 128
encoder_dim = 128
decoder_dim = 128
beam_size = 5
max_length = 120

# encoder
src_word_id = pd.data(
    name='source_language_word',
    type=pd.data.integer_value_sequence(source_dict_dim))
src_embedding = pd.embedding(size=source_dict_size, size=word_vector_dim)

src_word_vec = pd.lookup(src_embedding, src_word_id)

encoder_out_seq = pd.gru(input=src_word_vec, size=encoder_dim)

encoder_ctx = pd.last_seq(encoder_out_seq)
# encoder_ctx_proj is the learned semantic vector
encoder_ctx_proj = pd.fc(
    encoder_ctx, size=decoder_dim, act=pd.activation.Tanh(), bias=None)
```

**Decoder**

```python
def generate():
    decoder = pd.while_loop()
    with decoder.step():
        decoder_mem = decoder.memory(init=encoder_ctx)  # mark the memory
        generated_ids = decoder.memory() # TODO init to batch_size <s>s
        generated_scores = decoder.memory() # TODO init to batch_size 1s or 0s

        target_word = pd.lookup(trg_embedding, gendrated_ids)
        # expand encoder_ctx's batch to fit target_word's lod
        # for example
        # decoder_mem.lod is
        # [[0 1 3],
        #  [0 1 3 6]]
        # its tensor content is [a1 a2 a3 a4 a5]
        # which means there are 2 sentences to translate
        #   - the first sentence has 1 translation prefixes, the offsets are [0, 1)
        #   - the second sentence has 2 translation prefixes, the offsets are [1, 3) and [3, 6)
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        # the target_word.lod is
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        # [[0, 1, 6]
        #  [0, 2, 4, 7, 9 12]]
        # which means 2 sentences to translate, each has 1 and 5 prefixes
        # the first prefix has 2 candidates
        # the following has 2, 3, 2, 3 candidates
        # the encoder_ctx_expanded's content will be
        # [a1 a1 a2 a2 a3 a3 a3 a4 a4 a5 a5 a5]
        encoder_ctx_expanded = pd.lod_expand(encoder_ctx, target_word)
        decoder_input = pd.fc(
            act=pd.activation.Linear(),
            input=[target_word, encoder_ctx],
            size=3 * decoder_dim)
        gru_out, cur_mem = pd.gru_step(
            decoder_input, mem=decoder_mem, size=decoder_dim)
        scores = pd.fc(
            gru_out,
            size=trg_dic_size,
            bias=None,
            act=pd.activation.Softmax())
        # K is an config
        topk_scores, topk_ids = pd.top_k(scores, K)
        topk_generated_scores = pd.add_scalar(topk_scores, generated_scores)

        selected_ids, selected_generation_scores = decoder.beam_search(
            topk_ids, topk_generated_scores)

        # update the states
        decoder_mem.update(cur_mem)  # tells how to update state
        generated_ids.update(selected_ids)
        generated_scores.update(selected_generation_scores)

        decoder.output(selected_ids)
        decoder.output(selected_generation_scores)

translation_ids, translation_scores = decoder()
```
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The `decoder.beam_search` is an operator that, given the candidates and the scores of translations including the candidates,
returns the result of the beam search algorithm.
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In this way, users can customize anything on the input or output of beam search, for example:
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1. Make the corresponding elements in `topk_generated_scores` zero or some small values, beam_search will discard this candidate.
2. Remove some specific candidate in `selected_ids`.
3. Get the final `translation_ids`, remove the translation sequence in it.
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The implementation of sequence decoder can reuse the C++ class:  [RNNAlgorithm](https://github.com/Superjom/Paddle/blob/68cac3c0f8451fe62a4cdf156747d6dc0ee000b3/paddle/operators/dynamic_recurrent_op.h#L30),
so the python syntax is quite similar to that of an  [RNN](https://github.com/Superjom/Paddle/blob/68cac3c0f8451fe62a4cdf156747d6dc0ee000b3/doc/design/block.md#blocks-with-for-and-rnnop).
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Both of them are two-level `LoDTensors`:
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- The first level represents `batch_size` of (source) sentences.
- The second level represents the candidate ID sets for translation prefix.
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For example, 3 source sentences to translate, and has 2, 3, 1 candidates.
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Unlike an RNN, in sequence decoder, the previous state and the current state have different LoD and shape, and an `lod_expand` operator is used to expand the LoD of the previous state to fit the current state.
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For example, the previous state:
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* LoD is `[0, 1, 3][0, 2, 5, 6]`
* content of tensor is `a1 a2 b1 b2 b3 c1`

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the current state is stored in `encoder_ctx_expanded`:
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* LoD is `[0, 2, 7][0 3 5 8 9 11 11]`
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* the content is
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  - a1 a1 a1 (a1 has 3 candidates, so the state should be copied 3 times for each candidates)
  - a2 a2
  - b1 b1 b1
  - b2
  - b3 b3
  - None (c1 has 0 candidates, so c1 is dropped)

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The benefit from the relative offset LoD is that the empty candidate set can be represented naturally.
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The status in each time step can be stored in `TensorArray`, and `Pack`ed to a final LoDTensor. The corresponding syntax is:
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```python
decoder.output(selected_ids)
decoder.output(selected_generation_scores)
```

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The `selected_ids` are the candidate ids for the prefixes, and will be `Packed` by `TensorArray` to a two-level `LoDTensor`, where the first level represents the source sequences and the second level represents generated sequences.
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Packing the `selected_scores` will get a `LoDTensor` that stores scores of each translation candidate.
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Packing the `selected_generation_scores` will get a `LoDTensor`, and each tail is the probability of the translation.
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## LoD and shape changes during decoding
<p align="center">
  <img src="./images/LOD-and-shape-changes-during-decoding.jpg"/>
</p>

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According to the image above, the only phase that changes the LoD is beam search.
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## Beam search design
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The beam search algorithm will be implemented as one method of the sequence decoder and has 3 inputs:
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1. `topk_ids`, the top K candidate ids for each prefix.
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2. `topk_scores`, the corresponding scores for `topk_ids`
3. `generated_scores`, the score of the prefixes.

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All of these are LoDTensors, so that the sequence affiliation is clear. Beam search will keep a beam for each prefix and select a smaller candidate set for each prefix.
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It will return three variables:
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1. `selected_ids`, the final candidate beam search function selected for the next step.
2. `selected_scores`, the scores for the candidates.
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3. `generated_scores`, the updated scores for each prefix (with the new candidates appended).
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## Introducing the LoD-based `Pack` and `Unpack` methods in `TensorArray`
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The `selected_ids`, `selected_scores` and `generated_scores` are LoDTensors that exist at each time step,
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so it is natural to store them in arrays.

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Currently, PaddlePaddle has a module called `TensorArray` which can store an array of tensors. It is better to store the results of beam search in a `TensorArray`.
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The `Pack` and `UnPack` in `TensorArray` are used to pack tensors in the array to an `LoDTensor` or split the `LoDTensor` to an array of tensors.
It needs some extensions to support the packing or unpacking an array of `LoDTensors`.