Enhance sequence_padding functor (CPU and GPU).

07972467 · yangyaming · 7c671466 · 07972467 · 07972467 · 07972467
6 changed file
--- a/paddle/fluid/operators/math/sequence_padding.cc
+++ b/paddle/fluid/operators/math/sequence_padding.cc
@@ -18,128 +18,111 @@ namespace paddle {
 namespace operators {
 namespace math {
-template <typename T>
+template <typename T, PaddingLayout padding_layout>
-class PaddingLoDTensorFunctor<platform::CPUDeviceContext, T> {
+void CopyDataCPU(framework::LoDTensor* seq_tensor,
- public:
+                 framework::Tensor* padding_tensor,
-  void operator()(const platform::CPUDeviceContext& context,
+                 const framework::Vector<size_t>& abs_offset,
-                  const framework::LoDTensor& seq, framework::Tensor* padding,
+                 const int64_t& max_seq_len, const int64_t& seq_width,
-                  bool norm_by_times) {
+                 bool seq_to_padding, bool norm_by_len) {
-    auto lod = seq.lod();
+  T* seq_data = seq_tensor->data<T>();
-    PADDLE_ENFORCE_GT(lod.size(), 0UL,
+  T* padding_data = padding_tensor->data<T>();
-                      "The LoD of LoDTensor seq should not be null.");
+  int64_t seq_num = abs_offset.size() - 1;
-    const size_t level = 0;
-    framework::LoD abs_offset_lod = framework::ToAbsOffset(lod);
+  for (int64_t i = 0; i < seq_num; ++i) {
+    int64_t seq_start = abs_offset[i];
-    auto seq_dims = seq.dims();
+    int64_t seq_len = abs_offset[i + 1] - seq_start;
-    PADDLE_ENFORCE_EQ(seq_dims[0],
-                      static_cast<int64_t>(abs_offset_lod[level].back()),
+    T scale = norm_by_len ? (1.0f / static_cast<T>(seq_len)) : 1.0f;
-                      "The first dimension of LoDTensor seq should be "
-                      "equal to the sum of all sequences's length.");
+    for (int64_t j = 0; j < seq_len; ++j) {
+      for (int64_t k = 0; k < seq_width; ++k) {
-    auto padding_dims = padding->dims();
+        size_t padding_offset = 0;
-    PADDLE_ENFORCE_EQ(padding_dims.size(), 3UL,
+        if (padding_layout == BATCH_LENGTH_WIDTH) {
-                      "The input padding should be a 3-D Tensor of shape "
+          padding_offset = (i * max_seq_len * seq_width) + j * seq_width + k;
-                      "[max_sequence_length, num_sequences, sequence_width].");
+        } else {
+          padding_offset = (j * seq_num * seq_width) + i * seq_width + k;
-    const int64_t max_sequence_length = MaximumSequenceLength(lod, level);
-    PADDLE_ENFORCE_EQ(padding_dims[0], max_sequence_length,
-                      "The first dimension of Tensor padding should be the "
-                      "maximum length of all sequences in LoDTensor seq.");
-    const int64_t num_sequences = abs_offset_lod[level].size() - 1;
-    PADDLE_ENFORCE_EQ(padding_dims[1], num_sequences,
-                      "The second dimension of Tensor padding should be the "
-                      "number of sequences in LoDTensor seq.");
-    const int64_t sequence_width = seq.numel() / seq_dims[0];
-    PADDLE_ENFORCE_EQ(padding_dims[2], sequence_width,
-                      "The third dimension of Tensor padding should be the "
-                      "width of sequence in LoDTensor seq.");
-    const T* seq_data = seq.data<T>();
-    T* padding_data = padding->data<T>();
-    for (int64_t i = 0; i < max_sequence_length; ++i) {
-      for (int64_t j = 0; j < num_sequences; ++j) {
-        int64_t start_pos = abs_offset_lod[level][j];
-        int64_t sequence_length = abs_offset_lod[level][j + 1] - start_pos;
-        if (i < sequence_length) {
-          // i > 0 => sequence_length > 0
-          T scale =
-              norm_by_times ? (1.0f / static_cast<T>(sequence_length)) : 1.0f;
-          for (int64_t k = 0; k < sequence_width; ++k) {
-            padding_data[(i * num_sequences + j) * sequence_width + k] =
-                seq_data[(start_pos + i) * sequence_width + k] * scale;
        }
+        if (seq_to_padding) {
+          padding_data[padding_offset] =
+              seq_data[(seq_start + j) * seq_width + k] * scale;
        } else {
-          memset(padding_data + (i * num_sequences + j) * sequence_width, 0,
+          seq_data[(seq_start + j) * seq_width + k] =
-                 sequence_width * sizeof(T));
+              padding_data[padding_offset] * scale;
        }
      }
    }
  }
-};
+}
-template <typename T>
+template <typename T, PaddingLayout padding_layout>
-class UnpaddingLoDTensorFunctor<platform::CPUDeviceContext, T> {
+class PaddingLoDTensorFunctor<platform::CPUDeviceContext, T, padding_layout> {
 public:
  void operator()(const platform::CPUDeviceContext& context,
-                  framework::LoDTensor* seq, const framework::Tensor& padding,
+                  const framework::LoDTensor& seq_tensor,
-                  bool norm_by_times) {
+                  framework::Tensor* padding_tensor,
-    auto lod = seq->lod();
+                  T padding_value = static_cast<T>(0),
-    PADDLE_ENFORCE_GT(lod.size(), 0UL,
+                  bool norm_by_times = false, size_t lod_level = 0) {
-                      "The LoD of LoDTensor seq should not be null.");
+    ValidateLoD(seq_tensor, lod_level);
-    const size_t level = 0;
+    auto& lod = seq_tensor.lod();
-    framework::LoD abs_offset_lod = framework::ToAbsOffset(lod);
+    auto& abs_offset = framework::ToAbsOffset(lod)[lod_level];
-    auto seq_dims = seq->dims();
+    auto seq_dims = seq_tensor.dims();
-    PADDLE_ENFORCE_EQ(seq_dims[0],
+    auto padding_dims = padding_tensor->dims();
-                      static_cast<int64_t>(abs_offset_lod[level].back()),
+    int64_t max_seq_len = MaximumSequenceLength(lod, lod_level);
-                      "The first dimension of LoDTensor seq should be "
+    int64_t seq_num = abs_offset.size() - 1;
-                      "equal to the sum of all sequences's length.");
+    int64_t seq_width = seq_tensor.numel() / seq_dims[0];
+    int64_t numel = max_seq_len * seq_num * seq_width;
-    auto padding_dims = padding.dims();
-    PADDLE_ENFORCE_EQ(padding_dims.size(), 3UL,
+    ValidateShape(seq_dims, abs_offset.back(), padding_dims, max_seq_len,
-                      "The input padding should be a 3-D Tensor of shape "
+                  seq_num, seq_width, padding_layout);
-                      "[max_sequnece_length, num_sequences, sequence_width].");
+    T* padding_data = padding_tensor->data<T>();
-    const int64_t max_sequence_length = MaximumSequenceLength(lod, level);
-    PADDLE_ENFORCE_EQ(padding_dims[0], max_sequence_length,
+    memset(padding_data, padding_value, numel * sizeof(T));
-                      "The first dimension of Tensor padding should be "
-                      "the maximum length of all sequences in LoDTensor seq.");
+    CopyDataCPU<T, padding_layout>(
+        const_cast<framework::LoDTensor*>(&seq_tensor), padding_tensor,
-    const int64_t num_sequences = abs_offset_lod[level].size() - 1;
+        abs_offset, max_seq_len, seq_width, true /* seq_to_padding */,
-    PADDLE_ENFORCE_EQ(padding_dims[1], num_sequences,
+        norm_by_times);
-                      "The second dimension of Tensor padding should be "
-                      "the number of sequences in LoDTensor seq.");
-    const int64_t sequence_width = seq->numel() / seq_dims[0];
-    PADDLE_ENFORCE_EQ(padding_dims[2], sequence_width,
-                      "The third dimension of Tensor padding should be the "
-                      "width of sequence in LoDTensor seq.");
-    const T* padding_data = padding.data<T>();
-    T* seq_data = seq->data<T>();
-    for (int64_t i = 0; i < num_sequences; ++i) {
-      int64_t start_pos = abs_offset_lod[level][i];
-      int64_t sequence_length = abs_offset_lod[level][i + 1] - start_pos;
-      for (int64_t j = 0; j < sequence_length; ++j) {
-        // sequence_width > j > 0
-        T scale =
-            norm_by_times ? (1.0f / static_cast<T>(sequence_length)) : 1.0f;
-        for (int64_t k = 0; k < sequence_width; ++k) {
-          seq_data[(start_pos + j) * sequence_width + k] =
-              padding_data[(j * num_sequences + i) * sequence_width + k] *
-              scale;
-        }
-      }
  }
+};
+template <typename T, PaddingLayout padding_layout>
+class UnpaddingLoDTensorFunctor<platform::CPUDeviceContext, T, padding_layout> {
+ public:
+  void operator()(const platform::CPUDeviceContext& context,
+                  framework::LoDTensor* seq_tensor,
+                  const framework::Tensor& padding_tensor,
+                  bool norm_by_times = false, size_t lod_level = 0) {
+    ValidateLoD(*seq_tensor, lod_level);
+    auto& lod = seq_tensor->lod();
+    auto& abs_offset = framework::ToAbsOffset(lod)[lod_level];
+    auto& seq_dims = seq_tensor->dims();
+    auto& padding_dims = padding_tensor.dims();
+    int64_t max_seq_len = MaximumSequenceLength(lod, lod_level);
+    int64_t seq_num = abs_offset.size() - 1;
+    int64_t seq_width = seq_tensor->numel() / seq_dims[0];
+    ValidateShape(seq_dims, abs_offset.back(), padding_dims, max_seq_len,
+                  seq_num, seq_width, padding_layout);
+    T* seq_data = seq_tensor->data<T>();
+    memset(seq_data, static_cast<T>(0), seq_tensor->numel() * sizeof(T));
+    CopyDataCPU<T, padding_layout>(
+        seq_tensor, const_cast<framework::Tensor*>(&padding_tensor), abs_offset,
+        max_seq_len, seq_width, false /* seq_to_padding */, norm_by_times);
  }
 };
-template class PaddingLoDTensorFunctor<platform::CPUDeviceContext, float>;
+template class PaddingLoDTensorFunctor<platform::CPUDeviceContext, float,
-template class UnpaddingLoDTensorFunctor<platform::CPUDeviceContext, float>;
+                                       LENGTH_BATCH_WIDTH>;
+template class UnpaddingLoDTensorFunctor<platform::CPUDeviceContext, float,
+                                         LENGTH_BATCH_WIDTH>;
 }  // namespace math
 }  // namespace operators

--- a/paddle/fluid/operators/math/sequence_padding.cu
+++ b/paddle/fluid/operators/math/sequence_padding.cu
@@ -19,87 +19,76 @@ namespace paddle {
 namespace operators {
 namespace math {
-template <typename T, bool NormByTimes, bool Padding>
+template <typename T, bool Padding>
-__global__ void SequencePaddingKernel(T* padding, T* sequence,
+__global__ void SequencePaddingKernel(
-                                      const size_t* sequence_start_positions,
+    T* padding_data, T* seq_data, const size_t* abs_offset,
-                                      const size_t sequence_width,
+    const size_t& seq_num, const size_t& max_seq_len, const size_t& seq_width,
-                                      const size_t max_sequence_length,
+    const PaddingLayout& padding_layout, bool norm_by_times = false,
-                                      const size_t num_sequences) {
+    const T& padding_value = 0) {
  size_t padding_idx = blockIdx.y;
-  size_t start_pos = sequence_start_positions[padding_idx];
+  size_t seq_start = abs_offset[padding_idx];
-  size_t sequence_length =
+  size_t seq_len = abs_offset[padding_idx + 1] - seq_start;
-      sequence_start_positions[padding_idx + 1] - start_pos;
-  size_t sequence_idx = blockIdx.x * blockDim.y + threadIdx.y;
+  size_t seq_idx = blockIdx.x * blockDim.y + threadIdx.y;
-  size_t padding_base_idx =
-      (sequence_idx * num_sequences + padding_idx) * sequence_width;
-  size_t sequence_base_idx = (start_pos + sequence_idx) * sequence_width;
-  if (sequence_idx < sequence_length) {
+  size_t seq_offset = (seq_start + seq_idx) * seq_width;
-    T scale = NormByTimes ? (1.0f / static_cast<T>(sequence_length)) : 1.0f;
+  size_t padding_offset = 0;
+  if (padding_layout == LENGTH_BATCH_WIDTH) {
+    padding_offset = (seq_idx * seq_num + padding_idx) * seq_width;
+  } else {
+    padding_offset = (padding_idx * max_seq_len + seq_idx) * seq_width;
+  }
+  if (seq_idx < seq_len) {
+    T scale = norm_by_times ? (1.0f / static_cast<T>(seq_len)) : 1.0f;
    if (Padding) {
      /* sequence -> padding */
-      for (size_t i = threadIdx.x; i < sequence_width; i += blockDim.x) {
+      for (size_t i = threadIdx.x; i < seq_width; i += blockDim.x) {
-        padding[padding_base_idx + i] = scale * sequence[sequence_base_idx + i];
+        padding_data[padding_offset + i] = scale * seq_data[seq_offset + i];
      }
    } else {
      /* padding -> sequence */
-      for (size_t i = threadIdx.x; i < sequence_width; i += blockDim.x) {
+      for (size_t i = threadIdx.x; i < seq_width; i += blockDim.x) {
-        sequence[sequence_base_idx + i] = scale * padding[padding_base_idx + i];
+        seq_data[seq_offset + i] = scale * padding_data[padding_offset + i];
      }
    }
-  } else if (sequence_idx < max_sequence_length) {
+  } else if (seq_idx < max_seq_len) {
    if (Padding) {
      /* sequence -> padding */
-      for (size_t i = threadIdx.x; i < sequence_width; i += blockDim.x) {
+      for (size_t i = threadIdx.x; i < seq_width; i += blockDim.x) {
-        padding[padding_base_idx + i] = 0;
+        padding_data[padding_offset + i] = padding_value;
      }
    }
  }
 }
-template <typename T>
+template <typename T, PaddingLayout padding_layout>
-class PaddingLoDTensorFunctor<platform::CUDADeviceContext, T> {
+class PaddingLoDTensorFunctor<platform::CUDADeviceContext, T, padding_layout> {
 public:
  void operator()(const platform::CUDADeviceContext& context,
-                  const framework::LoDTensor& seq, framework::Tensor* padding,
+                  const framework::LoDTensor& seq_tensor,
-                  bool norm_by_times) {
+                  framework::Tensor* padding_tensor,
-    auto lod = seq.lod();
+                  T padding_value = static_cast<T>(0),
-    PADDLE_ENFORCE_GT(lod.size(), 0UL,
+                  bool norm_by_times = false, size_t lod_level = 0) {
-                      "The lod of LoDTensor seq should not be null.");
+    ValidateLoD(seq_tensor, lod_level);
-    const size_t level = 0;
+    auto& lod = seq_tensor.lod();
-    framework::LoD abs_offset_lod = framework::ToAbsOffset(lod);
+    auto& abs_offset = framework::ToAbsOffset(lod)[lod_level];
-    auto seq_dims = seq.dims();
+    auto seq_dims = seq_tensor.dims();
-    PADDLE_ENFORCE_EQ(seq_dims[0],
+    auto padding_dims = padding_tensor->dims();
-                      static_cast<int64_t>(abs_offset_lod[level].back()),
+    int64_t max_seq_len = MaximumSequenceLength(lod, lod_level);
-                      "The first dimension of LoDTensor seq should be "
+    const int64_t seq_num = abs_offset.size() - 1;
-                      "equal to the sum of all sequences's length.");
+    const int64_t seq_width = seq_tensor.numel() / seq_dims[0];
-    auto padding_dims = padding->dims();
+    ValidateShape(seq_dims, abs_offset.back(), padding_dims, max_seq_len,
-    PADDLE_ENFORCE_EQ(padding_dims.size(), 3UL,
+                  seq_num, seq_width, padding_layout);
-                      "The input padding should be a 3-D Tensor of shape "
-                      "[max_sequence_length, num_sequences, sequence_width].");
+    if (!norm_by_times && seq_num == 1UL) {
+      TensorCopy(seq_tensor, context.GetPlace(), context, padding_tensor);
-    int64_t max_sequence_length = MaximumSequenceLength(lod, level);
+      padding_tensor->Resize(padding_dims);
-    PADDLE_ENFORCE_EQ(padding_dims[0], max_sequence_length,
-                      "The first dimension of Tensor padding should be the "
-                      "maximum length of all sequences in LoDTensor seq.");
-    const int64_t num_sequences = abs_offset_lod[level].size() - 1;
-    PADDLE_ENFORCE_EQ(padding_dims[1], num_sequences,
-                      "The second dimension of Tensor padding should be the "
-                      "number of sequences in LoDTensor seq.");
-    const int64_t sequence_width = seq.numel() / seq_dims[0];
-    PADDLE_ENFORCE_EQ(padding_dims[2], sequence_width,
-                      "The third dimension of Tensor padding should be the "
-                      "width of sequence in LoDTensor seq.");
-    if (!norm_by_times && num_sequences == 1UL) {
-      TensorCopy(seq, context.GetPlace(), context, padding);
-      padding->Resize(padding_dims);
      return;
    }
@@ -109,72 +98,46 @@ class PaddingLoDTensorFunctor<platform::CUDADeviceContext, T> {
     * and at least 8 elements for each thread.
     */
    size_t block_dim_x =
-        std::min(((((sequence_width + 7) >> 3) + 31) >> 5) << 5, kBlockSize);
+        std::min(((((seq_width + 7) >> 3) + 31) >> 5) << 5, kBlockSize);
    size_t block_dim_y = kBlockSize / block_dim_x;
    dim3 threads(block_dim_x, block_dim_y);
-    size_t grid_dim_x = (max_sequence_length + block_dim_y - 1) / block_dim_y;
+    size_t grid_dim_x = (max_seq_len + block_dim_y - 1) / block_dim_y;
-    size_t grid_dim_y = num_sequences;
+    size_t grid_dim_y = seq_num;
    dim3 grid(grid_dim_x, grid_dim_y);
-    const T* seq_data = seq.data<T>();
+    const T* seq_data = seq_tensor.data<T>();
-    T* padding_data = padding->data<T>();
+    T* padding_data = padding_tensor->data<T>();
-    if (norm_by_times) {
-      SequencePaddingKernel<T, 1, 1><<<grid, threads, 0, context.stream()>>>(
+    SequencePaddingKernel<T, 1><<<grid, threads, 0, context.stream()>>>(
-          padding_data, const_cast<T*>(seq_data),
-          abs_offset_lod[level].CUDAData(context.GetPlace()), sequence_width,
-          max_sequence_length, num_sequences);
-    } else {
-      SequencePaddingKernel<T, 0, 1><<<grid, threads, 0, context.stream()>>>(
        padding_data, const_cast<T*>(seq_data),
-          abs_offset_lod[level].CUDAData(context.GetPlace()), sequence_width,
+        abs_offset.CUDAData(context.GetPlace()), seq_num, max_seq_len,
-          max_sequence_length, num_sequences);
+        seq_width, padding_layout, norm_by_times, padding_value);
-    }
  }
 };
-template <typename T>
+template <typename T, PaddingLayout padding_layout>
-class UnpaddingLoDTensorFunctor<platform::CUDADeviceContext, T> {
+class UnpaddingLoDTensorFunctor<platform::CUDADeviceContext, T,
+                                padding_layout> {
 public:
  void operator()(const platform::CUDADeviceContext& context,
-                  framework::LoDTensor* seq, const framework::Tensor& padding,
+                  framework::LoDTensor* seq_tensor,
-                  bool norm_by_times) {
+                  const framework::Tensor& padding_tensor,
-    auto lod = seq->lod();
+                  bool norm_by_times = false, size_t lod_level = 0) {
-    PADDLE_ENFORCE_GT(lod.size(), 0UL,
+    ValidateLoD(*seq_tensor, lod_level);
-                      "The lod of LoDTensor seq should not be null.");
+    auto& lod = seq_tensor->lod();
-    const size_t level = 0;
+    auto& abs_offset = framework::ToAbsOffset(lod)[lod_level];
-    framework::LoD abs_offset_lod = framework::ToAbsOffset(lod);
+    auto seq_dims = seq_tensor->dims();
-    auto seq_dims = seq->dims();
+    auto padding_dims = padding_tensor.dims();
-    PADDLE_ENFORCE_EQ(seq_dims[0],
+    int64_t max_seq_len = MaximumSequenceLength(lod, lod_level);
-                      static_cast<int64_t>(abs_offset_lod[level].back()),
+    int64_t seq_num = abs_offset.size() - 1;
-                      "The first dimension of LoDTensor seq should be "
+    int64_t seq_width = seq_tensor->numel() / seq_dims[0];
-                      "equal to the sum of all sequences's length.");
+    if (!norm_by_times && seq_num == 1UL) {
-    auto padding_dims = padding.dims();
+      TensorCopy(padding_tensor, context.GetPlace(), context, seq_tensor);
-    PADDLE_ENFORCE_EQ(padding_dims.size(), 3UL,
+      seq_tensor->Resize(seq_dims);
-                      "The input padding should be a 3-D Tensor of shape "
-                      "[max_sequnece_length, num_sequences, sequence_width].");
-    int64_t max_sequence_length = MaximumSequenceLength(lod, level);
-    PADDLE_ENFORCE_EQ(padding_dims[0], max_sequence_length,
-                      "The first dimension of Tensor padding should be "
-                      "the maximum length of all sequences in LoDTensor seq.");
-    const int64_t num_sequences = abs_offset_lod[level].size() - 1;
-    PADDLE_ENFORCE_EQ(padding_dims[1], num_sequences,
-                      "The second dimension of Tensor padding should be "
-                      "the number of sequences in LoDTensor seq.");
-    const int64_t sequence_width = seq->numel() / seq_dims[0];
-    PADDLE_ENFORCE_EQ(padding_dims[2], sequence_width,
-                      "The third dimension of Tensor padding should be the "
-                      "width of sequence in LoDTensor seq.");
-    if (!norm_by_times && num_sequences == 1UL) {
-      TensorCopy(padding, context.GetPlace(), context, seq);
-      seq->Resize(seq_dims);
      return;
    }
@@ -184,32 +147,28 @@ class UnpaddingLoDTensorFunctor<platform::CUDADeviceContext, T> {
     * and at least 8 elements for each thread.
     */
    size_t block_dim_x =
-        std::min(((((sequence_width + 7) >> 3) + 31) >> 5) << 5, kBlockSize);
+        std::min(((((seq_width + 7) >> 3) + 31) >> 5) << 5, kBlockSize);
    size_t block_dim_y = kBlockSize / block_dim_x;
    dim3 threads(block_dim_x, block_dim_y);
-    size_t grid_dim_x = (max_sequence_length + block_dim_y - 1) / block_dim_y;
+    size_t grid_dim_x = (max_seq_len + block_dim_y - 1) / block_dim_y;
-    size_t grid_dim_y = num_sequences;
+    size_t grid_dim_y = seq_num;
    dim3 grid(grid_dim_x, grid_dim_y);
-    const T* padding_data = padding.data<T>();
+    const T* padding_data = padding_tensor.data<T>();
-    T* seq_data = seq->data<T>();
+    T* seq_data = seq_tensor->data<T>();
-    if (norm_by_times) {
-      SequencePaddingKernel<T, 1, 0><<<grid, threads, 0, context.stream()>>>(
+    SequencePaddingKernel<T, 1><<<grid, threads, 0, context.stream()>>>(
-          const_cast<T*>(padding_data), seq_data,
-          abs_offset_lod[level].CUDAData(context.GetPlace()), sequence_width,
-          max_sequence_length, num_sequences);
-    } else {
-      SequencePaddingKernel<T, 0, 0><<<grid, threads, 0, context.stream()>>>(
        const_cast<T*>(padding_data), seq_data,
-          abs_offset_lod[level].CUDAData(context.GetPlace()), sequence_width,
+        abs_offset.CUDAData(context.GetPlace()), seq_num, max_seq_len,
-          max_sequence_length, num_sequences);
+        seq_width, padding_layout, norm_by_times);
-    }
  }
 };
-template class PaddingLoDTensorFunctor<platform::CUDADeviceContext, float>;
+template class PaddingLoDTensorFunctor<platform::CUDADeviceContext, float,
-template class UnpaddingLoDTensorFunctor<platform::CUDADeviceContext, float>;
+                                       LENGTH_BATCH_WIDTH>;
+template class UnpaddingLoDTensorFunctor<platform::CUDADeviceContext, float,
+                                         LENGTH_BATCH_WIDTH>;
 }  // namespace math
 }  // namespace operators

--- a/paddle/fluid/operators/math/sequence_padding.h
+++ b/paddle/fluid/operators/math/sequence_padding.h
@@ -22,17 +22,50 @@ namespace paddle {
 namespace operators {
 namespace math {
+enum PaddingLayout { BATCH_LENGTH_WIDTH, LENGTH_BATCH_WIDTH };
 inline static size_t MaximumSequenceLength(const framework::LoD& lod,
                                           const size_t level) {
-  const size_t num_sequences = lod[level].size() - 1;
+  const size_t seq_num = lod[level].size() - 1;
-  size_t max_sequence_length = 0;
+  size_t max_seq_len = 0;
-  framework::LoD abs_offset_lod = framework::ToAbsOffset(lod);
+  auto abs_offset = framework::ToAbsOffset(lod)[level];
-  for (size_t i = 0; i < num_sequences; ++i) {
+  for (size_t i = 0; i < seq_num; ++i) {
-    max_sequence_length =
+    max_seq_len = std::max(max_seq_len, abs_offset[i + 1] - abs_offset[i]);
-        std::max(max_sequence_length,
+  }
-                 abs_offset_lod[level][i + 1] - abs_offset_lod[level][i]);
+  return max_seq_len;
+}
+inline static void ValidateLoD(const framework::LoDTensor& seq_tensor,
+                               const size_t& lod_level) {
+  PADDLE_ENFORCE(lod_level < seq_tensor.lod().size(),
+                 "Invalid `lod_level` which should be at least 0 and less "
+                 "than maximum lod level of `seq_tensor`.");
+}
+inline static void ValidateShape(const framework::DDim& seq_tensor_dims,
+                                 const size_t& abs_offset_back_value,
+                                 const framework::DDim& padding_tensor_dims,
+                                 const int64_t& max_seq_len,
+                                 const int64_t& seq_num,
+                                 const int64_t& seq_width,
+                                 const PaddingLayout& padding_layout) {
+  PADDLE_ENFORCE_EQ(static_cast<size_t>(seq_tensor_dims[0]),
+                    abs_offset_back_value,
+                    "The 1st dimension of `seq_tensor` should be equal to "
+                    "sum of lengths of all sequences.");
+  PADDLE_ENFORCE_EQ(padding_tensor_dims.size(), 3UL,
+                    "`padding_tensor` should be a 3-D tensor.");
+  if (padding_layout == BATCH_LENGTH_WIDTH) {
+    PADDLE_ENFORCE_EQ(padding_tensor_dims,
+                      framework::make_ddim({seq_num, max_seq_len, seq_width}));
+  } else if (padding_layout == LENGTH_BATCH_WIDTH) {
+    PADDLE_ENFORCE_EQ(padding_tensor_dims,
+                      framework::make_ddim({max_seq_len, seq_num, seq_width}));
+  } else {
+    PADDLE_THROW("Unsupported padding layout.");
  }
-  return max_sequence_length;
 }
 /*
@@ -61,18 +94,23 @@ inline static size_t MaximumSequenceLength(const framework::LoD& lod,
 *
 * \note  transposition is also done in this functor.
 */
-template <typename DeviceContext, typename T>
+template <typename DeviceContext, typename T, PaddingLayout padding_layout>
 class PaddingLoDTensorFunctor {
 public:
-  void operator()(const DeviceContext& context, const framework::LoDTensor& seq,
+  void operator()(const DeviceContext& context,
-                  framework::Tensor* padding, bool norm_by_times);
+                  const framework::LoDTensor& seq_tensor,
+                  framework::Tensor* padding_tensor,
+                  T padding_value = static_cast<T>(0),
+                  bool norm_by_times = false, size_t lod_level = 0);
 };
-template <typename DeviceContext, typename T>
+template <typename DeviceContext, typename T, PaddingLayout padding_layout>
 class UnpaddingLoDTensorFunctor {
 public:
-  void operator()(const DeviceContext& context, framework::LoDTensor* seq,
+  void operator()(const DeviceContext& context,
-                  const framework::Tensor& padding, bool norm_by_times);
+                  framework::LoDTensor* seq_tensor,
+                  const framework::Tensor& padding_tensor,
+                  bool norm_by_times = false, size_t lod_level = 0);
 };
 }  // namespace math

--- a/paddle/fluid/operators/sequence_pad_op.cc
+++ b/paddle/fluid/operators/sequence_pad_op.cc
@@ -32,7 +32,11 @@ class SequencePadOp : public framework::OperatorWithKernel {
    PADDLE_ENFORCE_EQ(x_dims.size(), 2,
                      "Only support 2-D tensor, rank of Input(X) should be 2.");
-    auto out_dims = x_dims;
+    int lod_level = ctx->Attrs().Get<int>("lod_level");
+    int64_t max_len = -1;
+    int64_t seq_num = -1;
+    int x_lod_size = -1;
    if (ctx->IsRuntime()) {
      framework::Variable* x_var =
@@ -40,27 +44,31 @@ class SequencePadOp : public framework::OperatorWithKernel {
      auto& x_lod = x_var->Get<LoDTensor>().lod();
-      PADDLE_ENFORCE_GE(x_lod.size(), 1,
+      x_lod_size = x_lod.size();
-                        "Input(X) should be sequences containing lod.");
+      auto x_abs_offset = framework::ToAbsOffset(x_lod)[lod_level];
+      PADDLE_ENFORCE_EQ(x_dims[0], static_cast<int64_t>(x_abs_offset.back()),
+                        "The first dimension of `X` should be equal to sum "
+                        "of all sequences' length.");
-      auto last_level_lod = x_lod[x_lod.size() - 1];
+      seq_num = x_abs_offset.size() - 1;
-      size_t max_len = 0;
-      for (size_t i = 1; i < last_level_lod.size(); ++i) {
+      for (size_t i = 1; i <= seq_num; ++i) {
-        auto seq_len = last_level_lod[i] - last_level_lod[i - 1];
+        int64_t seq_len = x_abs_offset[i] - x_abs_offset[i - 1];
        max_len = max_len < seq_len ? seq_len : max_len;
      }
-      out_dims[0] = max_len * (last_level_lod.size() - 1);
    } else {
      framework::VarDesc* x_desc =
          boost::get<framework::VarDesc*>(ctx->GetInputVarPtrs("X")[0]);
-      PADDLE_ENFORCE_GE(x_desc->GetLoDLevel(), 1,
+      x_lod_size = x_desc->GetLoDLevel();
-                        "Input(X) should be sequences containing lod.");
-      out_dims[0] = -1;
    }
-    ctx->SetOutputDim("Out", out_dims);
+    PADDLE_ENFORCE(lod_level >= 0 && lod_level < x_lod_size,
+                   "Invalid `lod_level` which should be at least 0 and less "
+                   "than maximum lod level of `X`");
+    ctx->SetOutputDim("Out", {seq_num, max_len, x_dims[1]});
  }
 protected:
@@ -84,9 +92,11 @@ class SequencePadOpMaker : public framework::OpProtoAndCheckerMaker {
              "(Tensor) Output variable which would be a common tensor "
              "without lod. Each sequence would be padded to the maximum "
              "length.");
+    AddAttr<float>("lod_level",
+                   "(int, default 0) Specify which level lod to referred to.");
    AddAttr<float>("pad_value",
-                   "(float, default 0.0) Value to be padded "
+                   "(float, default 0.0) Specify which value to be padded to "
-                   "to the end of each sequence.");
+                   "the end of each sequence.");
    AddComment(R"DOC(
    )DOC");

--- a/paddle/fluid/operators/sequence_pad_op.h
+++ b/paddle/fluid/operators/sequence_pad_op.h
@@ -16,6 +16,7 @@ limitations under the License. */
 #include "paddle/fluid/framework/op_registry.h"
 #include "paddle/fluid/memory/memcpy.h"
 #include "paddle/fluid/operators/math/math_function.h"
+#include "paddle/fluid/operators/math/sequence_padding.h"
 namespace paddle {
 namespace operators {
@@ -23,39 +24,68 @@ namespace operators {
 using LoDTensor = framework::LoDTensor;
 using LoD = framework::LoD;
-// @TODO clean code
+template <typename DeviceContext, typename T>
+struct CopyFunctor {
+  LoDTensor* lod_tensor_;
+  LoDTensor* pad_tensor_;
+  const LoD& ref_lod_;
+  const DeviceContext& ctx_;
+  bool is_lod_to_pad_;
+  CopyFunctor(LoDTensor* lod_tensor, const LoD& ref_lod, LoDTensor* pad_tensor,
+              const DeviceContext& ctx, bool is_lod_to_pad)
+      : lod_tensor_(lod_tensor),
+        pad_tensor_(pad_tensor),
+        ref_lod_(ref_lod),
+        ctx_(ctx),
+        is_lod_to_pad_(is_lod_to_pad) {}
+  void operator()() const {
+    /*
+    auto seq_num = ref_lod_.size() - 1;
+    auto max_len = pad_tensor_->dims()[0] / seq_num;
+    PADDLE_ENFORCE_EQ(max_len * seq_num, pad_tensor_->dims()[0],
+                      "First dimension of padded tensor should be equal to "
+                      "maximum sequence length mulplied by sequence number.");
+    for (size_t i = 1; i < ref_lod_.size(); ++i) {
+      auto seq_start = ref_lod_[i - 1];
+      auto seq_end = ref_lod_[i];
+      auto pad_start = (i - 1) * max_len;
+      auto pad_end = pad_start + (seq_end - seq_start);
+      auto sub_lod_tensor = lod_tensor_->Slice(seq_start, seq_end);
+      auto sub_pad_tensor = pad_tensor_->Slice(pad_start, pad_end);
+      if (is_lod_to_pad_) {
+        framework::TensorCopy(sub_lod_tensor, ctx.GetPlace(), &sub_pad_tensor);
+      } else {
+        framework::TensorCopy(sub_pad_tensor, ctx.GetPlace(), &sub_lod_tensor);
+      }
+    }
+    */
+  }
+};
 template <typename DeviceContext, typename T>
 class SequencePadOpKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& ctx) const override {
-    auto* x_ptr = ctx.Input<LoDTensor>("X");
+    /*
+    auto* x = ctx.Input<LoDTensor>("X");
    auto* out_ptr = ctx.Output<LoDTensor>("Out");
    out_ptr->mutable_data<T>(ctx.GetPlace());
+    // Resize();
    T pad_value = static_cast<T>(ctx.Attr<float>("pad_value"));
+    math::PaddingLoDTensorFunctor<DeviceContext, T>()(
+        ctx.template device_context<DeviceContext>(), *x, *, false);
    math::SetConstant<DeviceContext, T> set_func;
    set_func(ctx.template device_context<DeviceContext>(), out_ptr, pad_value);
+    */
-    auto& x_lod = x_ptr->lod();
-    auto& x_last_level_lod = x_lod[x_lod.size() - 1];
-    auto seq_num = x_last_level_lod.size() - 1;
-    auto max_len = out_ptr->dims()[0] / seq_num;
-    PADDLE_ENFORCE_EQ(max_len * seq_num, out_ptr->dims()[0],
-                      "First dimension of `Out` should be equal to "
-                      "maximum length mulplied by sequence number.");
-    for (size_t i = 1; i < x_last_level_lod.size(); ++i) {
-      auto x_start = x_last_level_lod[i - 1];
-      auto x_end = x_last_level_lod[i];
-      auto out_start = (i - 1) * max_len;
-      auto out_end = out_start + (x_end - x_start);
-      auto x_sub_tensor = x_ptr->Slice(x_start, x_end);
-      auto out_sub_tensor = out_ptr->Slice(out_start, out_end);
-      framework::TensorCopy(x_sub_tensor, ctx.GetPlace(), &out_sub_tensor);
-    }
  }
 };
@@ -63,33 +93,26 @@ template <typename DeviceContext, typename T>
 class SequencePadGradOpKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& ctx) const override {
+    /*
    auto* x_ptr = ctx.Input<LoDTensor>("X");
    auto* g_out_ptr = ctx.Input<LoDTensor>(framework::GradVarName("Out"));
    auto* g_x_ptr = ctx.Output<LoDTensor>(framework::GradVarName("X"));
    math::SetConstant<DeviceContext, T> set_func;
-    set_func(ctx.template device_context<DeviceContext>(), g_x_ptr,
+    set_func(ctx.template device_context<DeviceContext>(),
+             g_x_ptr,
             static_cast<T>(0));
    auto& x_lod = x_ptr->lod();
    auto& x_last_level_lod = x_lod[x_lod.size() - 1];
-    auto seq_num = x_last_level_lod.size() - 1;
-    int64_t max_len = g_out_ptr->dims()[0] / seq_num;
+    CopyFunctor copy_func<DeviceContext, T>(g_out_ptr,
+                                            x_last_level_lod,
-    PADDLE_ENFORCE_EQ(max_len * seq_num, g_out_ptr->dims()[0],
+                                            g_x_ptr,
-                      "First dimension of `Out` should be equal to "
+                                            ctx,
-                      "maximum length mulplied by sequence number.");
+                                            false);
+    copy_func();
-    for (size_t i = 1; i < x_last_level_lod.size(); ++i) {
+    */
-      auto x_start = x_last_level_lod[i - 1];
-      auto x_end = x_last_level_lod[i];
-      auto out_start = (i - 1) * max_len;
-      auto out_end = out_start + (x_end - x_start);
-      auto g_out_sub = g_out_ptr->Slice(out_start, out_end);
-      auto g_x_sub = g_x_ptr->Slice(x_start, x_end);
-      framework::TensorCopy(g_x_sub, ctx.GetPlace(), &g_out_sub);
-    }
  }
 };

--- a/paddle/fluid/operators/warpctc_op.h
+++ b/paddle/fluid/operators/warpctc_op.h
@@ -161,7 +161,7 @@ class WarpCTCKernel : public framework::OpKernel<T> {
                              static_cast<int64_t>(num_sequences),
                              static_cast<int64_t>(sequence_width)});
    warpctc_logits.mutable_data<T>(warpctc_logits_dims, ctx.GetPlace());
-    math::PaddingLoDTensorFunctor<DeviceContext, T>()(
+    math::PaddingLoDTensorFunctor<DeviceContext, T, math::LENGTH_BATCH_WIDTH>()(
        ctx.template device_context<DeviceContext>(), *logits, &warpctc_logits,
        false);
    const T* warpctc_logits_data = warpctc_logits.data<T>();
@@ -216,7 +216,8 @@ class WarpCTCGradKernel : public framework::OpKernel<T> {
    logits_grad->mutable_data<T>(ctx.GetPlace());
    bool norm_by_times = ctx.Attr<bool>("norm_by_times");
-    math::UnpaddingLoDTensorFunctor<DeviceContext, T>()(
+    math::UnpaddingLoDTensorFunctor<DeviceContext, T,
+                                    math::LENGTH_BATCH_WIDTH>()(
        ctx.template device_context<DeviceContext>(), logits_grad,
        *warpctc_grad, norm_by_times);