[MSLITE][Develop] optimize arm cpu fp32 op gru: use matmul

4 years ago · 53568e0e8b
--- a/mindspore/lite/nnacl/fp32/gru_fp32.c
+++ b/mindspore/lite/nnacl/fp32/gru_fp32.c
@@ -18,115 +18,126 @@
 #include "nnacl/fp32/lstm_fp32.h"
 #include "nnacl/fp32/activation_fp32.h"
 #include "nnacl/fp32/arithmetic_fp32.h"
 void InitGruGate(float *gate_buffer, const float *bias, const GruParameter *gru_parm) {
  int gate_offest = 0;
  for (int l = 0; l < 3; l++) {
    int batch_offest = gate_offest;
    int bias_offest = l * gru_parm->hidden_size_;
    for (int b = 0; b < gru_parm->batch_; b++) {
      memcpy(gate_buffer + batch_offest, bias + bias_offest, gru_parm->hidden_size_ * sizeof(float));
      batch_offest += gru_parm->hidden_size_;
    }
    gate_offest += gru_parm->batch_ * gru_parm->hidden_size_;
 #include "nnacl/fp32/matmul_fp32.h"
 void UpdateGruInputGate(float *gate_buffer, const float *input, const float *weight, const float *bias, int row,
                        int deep, int col, int col_align, bool is_vec) {
  for (int i = 0; i < 3; i++) {
    const float *weight_i = weight + deep * col * i;
    const float *bias_i = bias + col_align * i;
    float *gate = gate_buffer + row * col * i;
    LstmMatMul(gate, input, weight_i, bias_i, row, deep, col, is_vec);
  }
 }
 void GruStepUnit(float *output, const float *input, const float *input_reset_weight, const float *input_update_weight,
                 const float *input_hidden_weight, const float *state_reset_weight, const float *state_update_weight,
                 const float *state_hidden_weight, const float *bias, float *hidden_state, float *gate_buffer,
                 const GruParameter *gru_parm) {
  InitGruGate(gate_buffer, bias, gru_parm);
  float *update_gate = gate_buffer;
  float *reset_gate = gate_buffer + gru_parm->batch_ * gru_parm->hidden_size_;
  float *hidden_buffer = gate_buffer + gru_parm->batch_ * gru_parm->hidden_size_ * 2;
 void GruStepUnit(float *output, const float *input, const float *input_weight, const float *state_weight,
                 const float *bias, float *hidden_state, float *gate_buffer, float *matmul_buffer[2],
                 const GruParameter *gru_param) {
  bool is_vec = gru_param->batch_ == 1;
  // input * weight
  MatMulAcc(reset_gate, input, input_reset_weight, gru_parm->batch_, gru_parm->hidden_size_, gru_parm->input_size_);
  MatMulAcc(update_gate, input, input_update_weight, gru_parm->batch_, gru_parm->hidden_size_, gru_parm->input_size_);
  MatMulAcc(hidden_buffer, input, input_hidden_weight, gru_parm->batch_, gru_parm->hidden_size_, gru_parm->input_size_);
  if (is_vec) {
    UpdateGruInputGate(gate_buffer, input, input_weight, bias, gru_param->batch_, gru_param->input_size_,
                       gru_param->hidden_size_, gru_param->col_align_, is_vec);
  } else {
    // pack input for matmul
    PackLstmInput(matmul_buffer[0], input, gru_param->batch_, gru_param->input_size_);
    UpdateGruInputGate(gate_buffer, matmul_buffer[0], input_weight, bias, gru_param->batch_, gru_param->input_size_,
                       gru_param->hidden_size_, gru_param->col_align_, is_vec);
  }
  const float *state_update_weight = state_weight;
  const float *state_reset_weight = state_weight + gru_param->hidden_size_ * gru_param->hidden_size_;
  const float *state_hidden_weight = state_weight + gru_param->hidden_size_ * gru_param->hidden_size_ * 2;
  float *state_update_gate = gate_buffer + gru_param->batch_ * gru_param->hidden_size_ * 3;
  float *state_reset_gate = gate_buffer + gru_param->batch_ * gru_param->hidden_size_ * 4;
  float *state_hidden_buffer = gate_buffer + gru_param->batch_ * gru_param->hidden_size_ * 5;
  const float *state_update_bias = bias + gru_param->hidden_size_ * 3;
  const float *state_reset_bias = bias + gru_param->hidden_size_ * 4;
  const float *state_hidden_bias = bias + gru_param->hidden_size_ * 5;
  // state * weight
  MatMulAcc(reset_gate, hidden_state, state_reset_weight, gru_parm->batch_, gru_parm->hidden_size_,
            gru_parm->hidden_size_);
  MatMulAcc(update_gate, hidden_state, state_update_weight, gru_parm->batch_, gru_parm->hidden_size_,
            gru_parm->hidden_size_);
  if (is_vec) {
    LstmMatMul(state_reset_gate, hidden_state, state_reset_weight, state_reset_bias, gru_param->batch_,
               gru_param->hidden_size_, gru_param->hidden_size_, is_vec);
    LstmMatMul(state_update_gate, hidden_state, state_update_weight, state_update_bias, gru_param->batch_,
               gru_param->hidden_size_, gru_param->hidden_size_, is_vec);
  } else {
    PackLstmInput(matmul_buffer[1], hidden_state, gru_param->batch_, gru_param->hidden_size_);
    LstmMatMul(state_reset_gate, matmul_buffer[1], state_reset_weight, state_reset_bias, gru_param->batch_,
               gru_param->hidden_size_, gru_param->hidden_size_, is_vec);
    LstmMatMul(state_update_gate, matmul_buffer[1], state_update_weight, state_update_bias, gru_param->batch_,
               gru_param->hidden_size_, gru_param->hidden_size_, is_vec);
  }
  ElementAdd(gate_buffer, state_update_gate, gate_buffer, gru_param->batch_ * gru_param->hidden_size_ * 2);
  float *update_gate = gate_buffer;
  float *reset_gate = gate_buffer + gru_param->batch_ * gru_param->hidden_size_;
  float *hidden_buffer = gate_buffer + gru_param->batch_ * gru_param->hidden_size_ * 2;
  // update reset_gate
  Sigmoid(reset_gate, gru_parm->batch_ * gru_parm->hidden_size_, reset_gate);
  Sigmoid(reset_gate, gru_param->batch_ * gru_param->hidden_size_, reset_gate);
  // update update_gate
  Sigmoid(update_gate, gru_parm->batch_ * gru_parm->hidden_size_, update_gate);
  ElementMul(hidden_state, reset_gate, reset_gate, gru_parm->batch_ * gru_parm->hidden_size_);
  MatMulAcc(hidden_buffer, reset_gate, state_hidden_weight, gru_parm->batch_, gru_parm->hidden_size_,
            gru_parm->hidden_size_);
  Sigmoid(update_gate, gru_param->batch_ * gru_param->hidden_size_, update_gate);
  ElementMul(hidden_state, reset_gate, reset_gate, gru_param->batch_ * gru_param->hidden_size_);
  if (is_vec) {
    LstmMatMul(state_hidden_buffer, reset_gate, state_hidden_weight, state_hidden_bias, gru_param->batch_,
               gru_param->hidden_size_, gru_param->hidden_size_, is_vec);
  } else {
    PackLstmInput(matmul_buffer[1], reset_gate, gru_param->batch_, gru_param->hidden_size_);
    LstmMatMul(state_hidden_buffer, matmul_buffer[1], state_hidden_weight, state_hidden_bias, gru_param->batch_,
               gru_param->hidden_size_, gru_param->hidden_size_, is_vec);
  }
  ElementAdd(hidden_buffer, state_hidden_buffer, hidden_buffer, gru_param->batch_ * gru_param->hidden_size_);
  Tanh(hidden_buffer, gru_parm->batch_ * gru_parm->hidden_size_, hidden_buffer);
  Tanh(hidden_buffer, gru_param->batch_ * gru_param->hidden_size_, hidden_buffer);
  ElementMul(update_gate, hidden_state, hidden_state, gru_parm->batch_ * gru_parm->hidden_size_);
  ElementMul(update_gate, hidden_state, hidden_state, gru_param->batch_ * gru_param->hidden_size_);
  ArithmeticParameter parameter;
  parameter.in_elements_num0_ = 1;
  parameter.in_elements_num1_ = gru_parm->batch_ * gru_parm->hidden_size_;
  parameter.in_elements_num1_ = gru_param->batch_ * gru_param->hidden_size_;
  const float one = 1.0f;
  ElementOptSub(&one, update_gate, update_gate, gru_parm->batch_ * gru_parm->hidden_size_, &parameter);
  ElementOptSub(&one, update_gate, update_gate, gru_param->batch_ * gru_param->hidden_size_, &parameter);
  ElementMulAcc(update_gate, hidden_buffer, hidden_state, gru_parm->batch_ * gru_parm->hidden_size_);
  ElementMulAcc(update_gate, hidden_buffer, hidden_state, gru_param->batch_ * gru_param->hidden_size_);
  memcpy(output, hidden_state, gru_parm->batch_ * gru_parm->hidden_size_ * sizeof(float));
  memcpy(output, hidden_state, gru_param->batch_ * gru_param->hidden_size_ * sizeof(float));
 }
 void Gru(float *output, const float *input, const float *weight_g, const float *weight_r, const float *bias,
         float *hidden_state, float *gate_buffer, int check_seq_len, const GruParameter *gru_parm) {
         float *hidden_state, float *gate_buffer, float *matmul_buffer[2], int check_seq_len,
         const GruParameter *gru_param) {
  // forward
  const float *input_update_weight = weight_g;
  const float *input_reset_weight = weight_g + gru_parm->input_size_ * gru_parm->hidden_size_;
  const float *input_hidden_weight = weight_g + gru_parm->input_size_ * gru_parm->hidden_size_ * 2;
  const float *state_update_weight = weight_r;
  const float *state_reset_weight = weight_r + gru_parm->hidden_size_ * gru_parm->hidden_size_;
  const float *state_hidden_weight = weight_r + gru_parm->hidden_size_ * gru_parm->hidden_size_ * 2;
  for (int t = 0; t < check_seq_len; t++) {
    const float *input_ptr = input + t * gru_parm->input_step_;
    float *output_ptr = output + t * gru_parm->output_step_;
    GruStepUnit(output_ptr, input_ptr, input_reset_weight, input_update_weight, input_hidden_weight, state_reset_weight,
                state_update_weight, state_hidden_weight, bias, hidden_state, gate_buffer, gru_parm);
    const float *input_ptr = input + t * gru_param->input_step_;
    float *output_ptr = output + t * gru_param->output_step_;
    GruStepUnit(output_ptr, input_ptr, weight_g, weight_r, bias, hidden_state, gate_buffer, matmul_buffer, gru_param);
  }
  // zero out extra fw outputs
  for (int t = check_seq_len; t < gru_parm->seq_len_; t++) {
    float *output_ptr = output + t * gru_parm->output_step_;
    for (int i = 0; i < gru_parm->batch_ * gru_parm->hidden_size_; i++) {
  for (int t = check_seq_len; t < gru_param->seq_len_; t++) {
    float *output_ptr = output + t * gru_param->output_step_;
    for (int i = 0; i < gru_param->batch_ * gru_param->hidden_size_; i++) {
      output_ptr[i] = 0.0f;
    }
  }
  // backward
  if (gru_parm->bidirectional_) {
    input_update_weight = weight_g + gru_parm->input_size_ * gru_parm->hidden_size_ * 3;
    input_reset_weight = weight_g + gru_parm->input_size_ * gru_parm->hidden_size_ * 4;
    input_hidden_weight = weight_g + gru_parm->input_size_ * gru_parm->hidden_size_ * 5;
    state_update_weight = weight_r + gru_parm->hidden_size_ * gru_parm->hidden_size_ * 3;
    state_reset_weight = weight_r + gru_parm->hidden_size_ * gru_parm->hidden_size_ * 4;
    state_hidden_weight = weight_r + gru_parm->hidden_size_ * gru_parm->hidden_size_ * 5;
    float *backward_output = output + gru_parm->batch_ * gru_parm->hidden_size_;
    const float *backward_bias = bias + 3 * gru_parm->hidden_size_;
    float *backward_hidden_state = hidden_state + gru_parm->batch_ * gru_parm->hidden_size_;
  if (gru_param->bidirectional_) {
    const float *backward_weight_g = weight_g + 3 * gru_param->col_align_ * gru_param->input_size_;
    const float *backward_weight_r = weight_r + 3 * gru_param->col_align_ * gru_param->hidden_size_;
    const float *backward_bias = bias + 6 * gru_param->hidden_size_;
    float *backward_output = output + gru_param->batch_ * gru_param->hidden_size_;
    float *backward_hidden_state = hidden_state + gru_param->batch_ * gru_param->hidden_size_;
    for (int t = check_seq_len - 1; t >= 0; t--) {
      const float *input_ptr = input + t * gru_parm->input_step_;
      float *output_ptr = backward_output + t * gru_parm->output_step_;
      GruStepUnit(output_ptr, input_ptr, input_reset_weight, input_update_weight, input_hidden_weight,
                  state_reset_weight, state_update_weight, state_hidden_weight, backward_bias, backward_hidden_state,
                  gate_buffer, gru_parm);
      const float *input_ptr = input + t * gru_param->input_step_;
      float *output_ptr = backward_output + t * gru_param->output_step_;
      GruStepUnit(output_ptr, input_ptr, backward_weight_g, backward_weight_r, backward_bias, backward_hidden_state,
                  gate_buffer, matmul_buffer, gru_param);
    }
    // zero out extra bw outputs
    for (int t = gru_parm->seq_len_ - 1; t >= check_seq_len; t--) {
      float *output_ptr = backward_output + t * gru_parm->output_step_;
      for (int i = 0; i < gru_parm->batch_ * gru_parm->hidden_size_; i++) {
    for (int t = gru_param->seq_len_ - 1; t >= check_seq_len; t--) {
      float *output_ptr = backward_output + t * gru_param->output_step_;
      for (int i = 0; i < gru_param->batch_ * gru_param->hidden_size_; i++) {
        output_ptr[i] = 0.0f;
      }
    }
--- a/mindspore/lite/nnacl/fp32/gru_fp32.h
+++ b/mindspore/lite/nnacl/fp32/gru_fp32.h
@@ -21,7 +21,8 @@
 extern "C" {
 #endif
 void Gru(float *output, const float *input, const float *weight_g, const float *weight_r, const float *bias,
         float *hidden_state, float *gate_buffer, int check_seq_len, const GruParameter *gru_parm);
         float *hidden_state, float *gate_buffer, float *matmul_buffer[2], int check_seq_len,
         const GruParameter *gru_parm);
 #ifdef __cplusplus
 }
 #endif
--- a/mindspore/lite/nnacl/fp32/lstm_fp32.c
+++ b/mindspore/lite/nnacl/fp32/lstm_fp32.c
@@ -21,6 +21,30 @@
 #include "nnacl/fp32/arithmetic_fp32.h"
 #include "nnacl/fp32/matmul_fp32.h"
 void PackLstmWeight(float *dst, const float *src, int batch, int deep, int col, int col_align) {
  for (int i = 0; i < batch; i++) {
    const float *src_batch = src + i * col * deep;
    float *dst_batch = dst + i * col_align * deep;
 #ifdef ENABLE_AVX
    RowMajor2Col16Major(src_batch, dst_batch, col, deep);
 #elif defined(ENABLE_ARM32)
    RowMajor2Col4Major(src_batch, dst_batch, col, deep);
 #else
    RowMajor2Col8Major(src_batch, dst_batch, col, deep);
 #endif
  }
 }
 void PackLstmInput(float *dst, const float *src, int row, int deep) {
 #ifdef ENABLE_AVX
  RowMajor2Col6Major(src, dst, row, deep);
 #elif defined(ENABLE_SSE)
  RowMajor2Col4Major(src, dst, row, deep);
 #else
  RowMajor2Col12Major(src, dst, row, deep);
 #endif
 }
 // input: [row, inner_size]; weight: [col, inner_size]; output: [row, col]
 void MatMulAcc(float *output, const float *input, const float *weight, int rows, int cols, int inner_size) {
  for (int r = 0; r < rows; r++) {
@@ -52,6 +76,15 @@ void MatMulAcc(float *output, const float *input, const float *weight, int rows,
  }
 }
 void LstmMatMul(float *c, const float *a, const float *b, const float *bias, int row, int deep, int col, bool is_vec) {
  if (is_vec) {
    memcpy(c, bias, col * sizeof(float));
    MatMulAcc(c, a, b, row, col, deep);
  } else {
    MatMulOpt(a, b, c, bias, ActType_No, deep, row, col, col, OutType_Nhwc);
  }
 }
 void ElementMulAcc(const float *input0, const float *input1, float *output, int element_size) {
  int index = 0;
 #ifdef ENABLE_ARM
@@ -121,74 +154,42 @@ void UpdataOutput(const float *cell_state, const float *output_gate, float *hidd
  }
 }
 void LstmMatmul(float *c, const float *a, const float *b, const float *bias, int row, int deep, int col, bool is_vec) {
  if (is_vec) {
    memcpy(c, bias, col * sizeof(float));
    MatMulAcc(c, a, b, row, col, deep);
  } else {
    MatMulOpt(a, b, c, bias, ActType_No, deep, row, col, col, OutType_Nhwc);
 void UpdateLstmGate(float *gate_buffer, const float *input, const float *weight, const float *bias, int row, int deep,
                    int col, int col_align, bool is_vec) {
  for (int i = 0; i < 4; i++) {
    const float *weight_i = weight + deep * col * i;
    const float *bias_i = bias + col_align * i;
    float *gate = gate_buffer + row * col * i;
    LstmMatMul(gate, input, weight_i, bias_i, row, deep, col, is_vec);
  }
 }
 void PackLstmInput(float *dst, const float *src, int row, int deep) {
 #ifdef ENABLE_AVX
  RowMajor2Col6Major(src, dst, row, deep);
 #elif defined(ENABLE_SSE)
  RowMajor2Col4Major(src, dst, row, deep);
 #else
  RowMajor2Col12Major(src, dst, row, deep);
 #endif
 }
 void UpdateGate(float *gate_buffer, const float *input, const float *weight, const float *bias, int row, int deep,
                int col, int col_align, bool is_vec) {
  const float *input_weight = weight;
  const float *forget_weight = weight + deep * col * 2;
  const float *cell_weight = weight + deep * col * 3;
  const float *output_weight = weight + deep * col;
  const float *input_bias = bias;
  const float *forget_bias = bias + col_align * 2;
  const float *cell_bias = bias + col_align * 3;
  const float *output_bias = bias + col_align;
  float *input_gate = gate_buffer;
  float *forget_gate = gate_buffer + row * col * 2;
  float *cell_gate = gate_buffer + row * col * 3;
  float *output_gate = gate_buffer + row * col;
  LstmMatmul(input_gate, input, input_weight, input_bias, row, deep, col, is_vec);
  LstmMatmul(forget_gate, input, forget_weight, forget_bias, row, deep, col, is_vec);
  LstmMatmul(cell_gate, input, cell_weight, cell_bias, row, deep, col, is_vec);
  LstmMatmul(output_gate, input, output_weight, output_bias, row, deep, col, is_vec);
 }
 void LstmStepUnit(float *output, const float *input, const float *input_weight, const float *state_weight,
                  const float *bias, float *hidden_state, float *cell_state, float *gate_buffer, float *state_buffer,
                  float *matmul_buffer[2], const LstmParameter *lstm_param) {
  bool is_vec = lstm_param->batch_ == 1;
  // input * weight
  if (is_vec) {
    UpdateGate(gate_buffer, input, input_weight, bias, lstm_param->batch_, lstm_param->input_size_,
               lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
    UpdateLstmGate(gate_buffer, input, input_weight, bias, lstm_param->batch_, lstm_param->input_size_,
                   lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
  } else {
    // pack input for matmul
    PackLstmInput(matmul_buffer[0], input, lstm_param->batch_, lstm_param->input_size_);
    UpdateGate(gate_buffer, matmul_buffer[0], input_weight, bias, lstm_param->batch_, lstm_param->input_size_,
               lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
    UpdateLstmGate(gate_buffer, matmul_buffer[0], input_weight, bias, lstm_param->batch_, lstm_param->input_size_,
                   lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
  }
  // state * weight
  float *state_gate = gate_buffer + lstm_param->batch_ * lstm_param->hidden_size_ * 4;
  const float *state_bias = bias + lstm_param->col_align_ * 4;
  if (is_vec) {
    UpdateGate(state_gate, hidden_state, state_weight, state_bias, lstm_param->batch_, lstm_param->hidden_size_,
               lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
    UpdateLstmGate(state_gate, hidden_state, state_weight, state_bias, lstm_param->batch_, lstm_param->hidden_size_,
                   lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
  } else {
    // pack state for matmul
    PackLstmInput(matmul_buffer[1], hidden_state, lstm_param->batch_, lstm_param->hidden_size_);
    UpdateGate(state_gate, matmul_buffer[1], state_weight, state_bias, lstm_param->batch_, lstm_param->hidden_size_,
               lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
    UpdateLstmGate(state_gate, matmul_buffer[1], state_weight, state_bias, lstm_param->batch_, lstm_param->hidden_size_,
                   lstm_param->hidden_size_, lstm_param->col_align_, is_vec);
  }
  ElementAdd(gate_buffer, state_gate, gate_buffer, 4 * lstm_param->batch_ * lstm_param->hidden_size_);
--- a/mindspore/lite/nnacl/fp32/lstm_fp32.h
+++ b/mindspore/lite/nnacl/fp32/lstm_fp32.h
@@ -21,7 +21,11 @@
 #ifdef __cplusplus
 extern "C" {
 #endif
 void MatMulAcc(float *output, const float *input, const float *weight, int rows, int cols, int inner_size);
 void PackLstmWeight(float *dst, const float *src, int batch, int deep, int col, int col_align);
 void PackLstmInput(float *dst, const float *src, int row, int deep);
 void LstmMatMul(float *c, const float *a, const float *b, const float *bias, int row, int deep, int col, bool is_vec);
 void ElementMulAcc(const float *input0, const float *input1, float *output, int element_size);
--- a/mindspore/lite/nnacl/gru_parameter.h
+++ b/mindspore/lite/nnacl/gru_parameter.h
@@ -30,6 +30,8 @@ typedef struct GruParameter {
  int input_step_;
  int output_step_;
  bool bidirectional_;
  int col_align_;
  int row_align_;
 } GruParameter;
 #endif  // MINDSPORE_LITE_NNACL_GRU_PARAMETER_H_
--- a/mindspore/lite/src/runtime/kernel/arm/fp32/gru_fp32.cc
+++ b/mindspore/lite/src/runtime/kernel/arm/fp32/gru_fp32.cc
@@ -19,6 +19,7 @@
 #include "src/kernel_registry.h"
 #include "include/errorcode.h"
 #include "nnacl/fp32/gru_fp32.h"
 #include "nnacl/fp32/lstm_fp32.h"
 using mindspore::kernel::KERNEL_ARCH::kCPU;
 using mindspore::lite::KernelRegistrar;
@@ -28,82 +29,109 @@ using mindspore::schema::PrimitiveType_Gru;
 namespace mindspore::kernel {
 void GruCPUKernel::FreeTmpBuffer() {
  if (gate_buffer_ != nullptr) {
    free(gate_buffer_);
    gate_buffer_ = nullptr;
  if (!is_vec_) {
    if (weight_g_ptr_ != nullptr) {
      free(weight_g_ptr_);
      weight_g_ptr_ = nullptr;
    }
    if (weight_r_ptr_ != nullptr) {
      free(weight_r_ptr_);
      weight_r_ptr_ = nullptr;
    }
    if (bias_ptr_ != nullptr) {
      free(bias_ptr_);
      bias_ptr_ = nullptr;
    }
  }
  if (bias_ptr_ != nullptr) {
    free(bias_ptr_);
    bias_ptr_ = nullptr;
 }
 void GruCPUKernel::FreeRunBuffer() {
  context_->allocator->Free(gate_buffer_);
  if (!is_vec_) {
    for (int i = 0; i < 2; i++) {
      context_->allocator->Free(matmul_buffer_[i]);
    }
  }
  weight_g_ptr_ = nullptr;
  weight_r_ptr_ = nullptr;
 }
 int GruCPUKernel::InitParam() {
  auto input = in_tensors_.front();
  MS_ASSERT(input != nullptr);
  std::vector<int> in_shape = input->shape();
  gru_parm_->seq_len_ = in_shape.at(0);
  gru_parm_->batch_ = in_shape.at(1);
  gru_parm_->input_size_ = in_shape.at(2);
  gru_param_->seq_len_ = in_shape.at(0);
  gru_param_->batch_ = in_shape.at(1);
  gru_param_->input_size_ = in_shape.at(2);
  auto weight_g = in_tensors_.at(1);
  MS_ASSERT(weight_g != nullptr);
  std::vector<int> w_shape = weight_g->shape();
  gru_parm_->hidden_size_ = w_shape.at(1) / 3;
  gru_parm_->input_step_ = gru_parm_->batch_ * gru_parm_->input_size_;
  gru_parm_->output_step_ = gru_parm_->bidirectional_ ? 2 * gru_parm_->batch_ * gru_parm_->hidden_size_
                                                      : gru_parm_->batch_ * gru_parm_->hidden_size_;
  return RET_OK;
 }
 int GruCPUKernel::InitBuffer() {
  gate_buffer_ = reinterpret_cast<float *>(malloc(3 * gru_parm_->batch_ * gru_parm_->hidden_size_ * sizeof(float)));
  if (gate_buffer_ == nullptr) {
    MS_LOG(ERROR) << "GruCPUKernel malloc gate_buffer error.";
    return RET_ERROR;
  }
  gru_param_->hidden_size_ = w_shape.at(1) / 3;
  gru_param_->input_step_ = gru_param_->batch_ * gru_param_->input_size_;
  gru_param_->output_step_ = gru_param_->bidirectional_ ? 2 * gru_param_->batch_ * gru_param_->hidden_size_
                                                        : gru_param_->batch_ * gru_param_->hidden_size_;
 #ifdef ENABLE_AVX
  row_tile_ = C6NUM;
  col_tile_ = C16NUM;
 #elif defined(ENABLE_ARM32)
  row_tile_ = C12NUM;
  col_tile_ = C4NUM;
 #elif defined(ENABLE_SSE)
  row_tile_ = C4NUM;
  col_tile_ = C8NUM;
 #else
  row_tile_ = C12NUM;
  col_tile_ = C8NUM;
 #endif
  is_vec_ = gru_param_->batch_ == 1;
  gru_param_->row_align_ = is_vec_ ? 1 : UP_ROUND(gru_param_->batch_, row_tile_);
  gru_param_->col_align_ = is_vec_ ? gru_param_->hidden_size_ : UP_ROUND(gru_param_->hidden_size_, col_tile_);
  return RET_OK;
 }
 int GruCPUKernel::InitWeightBias() {
  auto weight_gate = in_tensors_.at(1);
  MS_ASSERT(weight_gate != nullptr);
  weight_g_ptr_ = reinterpret_cast<float *>(malloc(weight_gate->ElementsNum() * sizeof(float)));
  if (weight_g_ptr_ == nullptr) {
    MS_LOG(ERROR) << "GruCPUKernel malloc weight_g_ptr_ error.";
    return RET_ERROR;
  }
  memcpy(weight_g_ptr_, weight_gate->data_c(), weight_gate->ElementsNum() * sizeof(float));
  auto weight_recu = in_tensors_.at(2);
  MS_ASSERT(weight_recu != nullptr);
  weight_r_ptr_ = reinterpret_cast<float *>(malloc(weight_recu->ElementsNum() * sizeof(float)));
  if (weight_r_ptr_ == nullptr) {
    MS_LOG(ERROR) << "GruCPUKernel malloc weight_r_ptr_ error.";
    return RET_ERROR;
  }
  memcpy(weight_r_ptr_, weight_recu->data_c(), weight_recu->ElementsNum() * sizeof(float));
  int bias_num = gru_parm_->bidirectional_ ? 2 * 3 * gru_parm_->hidden_size_ : 3 * gru_parm_->hidden_size_;
  bias_ptr_ = reinterpret_cast<float *>(malloc(bias_num * sizeof(float)));
  if (bias_ptr_ == nullptr) {
    MS_LOG(ERROR) << "GruCPUKernel malloc bias_ptr_ error.";
    return RET_ERROR;
  }
  auto bias_data = reinterpret_cast<float *>(in_tensors_.at(3)->data_c());
  const int state_bias_offset = 3 * gru_parm_->hidden_size_;
  for (int i = 0; i < state_bias_offset; i++) {
    bias_ptr_[i] = bias_data[i] + bias_data[i + state_bias_offset];
  }
  if (gru_parm_->bidirectional_) {
    bias_data += 3 * gru_parm_->hidden_size_ * 2;
    auto backward_bias = bias_ptr_ + 3 * gru_parm_->hidden_size_;
    for (int i = 0; i < state_bias_offset; i++) {
      backward_bias[i] = bias_data[i] + bias_data[i + state_bias_offset];
  auto weight_batch = gru_param_->bidirectional_ ? 6 : 3;
  if (!is_vec_) {
    // malloc and init input * weight right matrix buffer
    auto weight_g = in_tensors_.at(1);
    MS_ASSERT(weight_g != nullptr);
    weight_g_ptr_ = reinterpret_cast<float *>(
      malloc(weight_batch * gru_param_->col_align_ * gru_param_->input_size_ * sizeof(float)));
    if (weight_g_ptr_ == nullptr) {
      MS_LOG(ERROR) << "GruCPUKernel malloc weight_g_ptr_ error.";
      return RET_ERROR;
    }
    auto weight_i_data = reinterpret_cast<float *>(weight_g->data_c());
    PackLstmWeight(weight_g_ptr_, weight_i_data, weight_batch, gru_param_->input_size_, gru_param_->hidden_size_,
                   gru_param_->col_align_);
    // malloc and init state * weight right matrix buffer
    auto weight_r = in_tensors_.at(2);
    MS_ASSERT(weight_r != nullptr);
    weight_r_ptr_ = reinterpret_cast<float *>(
      malloc(weight_batch * gru_param_->col_align_ * gru_param_->hidden_size_ * sizeof(float)));
    if (weight_r_ptr_ == nullptr) {
      MS_LOG(ERROR) << "GruCPUKernel malloc weight_r_ptr_ error.";
      return RET_ERROR;
    }
    auto weight_r_data = reinterpret_cast<float *>(weight_r->data_c());
    PackLstmWeight(weight_r_ptr_, weight_r_data, weight_batch, gru_param_->hidden_size_, gru_param_->hidden_size_,
                   gru_param_->col_align_);
    // init bias
    int bias_batch = gru_param_->bidirectional_ ? 16 : 8;
    bias_ptr_ = reinterpret_cast<float *>(malloc(bias_batch * gru_param_->col_align_ * sizeof(float)));
    if (bias_ptr_ == nullptr) {
      MS_LOG(ERROR) << "GruCPUKernel malloc bias_ptr_ error.";
      return RET_ERROR;
    }
    memset(bias_ptr_, 0, bias_batch * gru_param_->col_align_ * sizeof(float));
    auto bias_data = reinterpret_cast<float *>(in_tensors_.at(3)->data_c());
    for (int i = 0; i < bias_batch; i++) {
      auto src_batch = bias_data + i * gru_param_->hidden_size_;
      auto dst_batch = bias_ptr_ + i * gru_param_->col_align_;
      memcpy(dst_batch, src_batch, gru_param_->hidden_size_ * sizeof(float));
    }
  }
  return RET_OK;
@@ -117,24 +145,42 @@ int GruCPUKernel::Init() {
 }
 int GruCPUKernel::ReSize() {
  FreeTmpBuffer();
  auto ret = InitParam();
  if (ret != RET_OK) {
    MS_LOG(ERROR) << "GruCPUKernel InitParam error.";
    return RET_ERROR;
  }
  FreeTmpBuffer();
  ret = InitWeightBias();
  if (ret != RET_OK) {
    MS_LOG(ERROR) << "GruCPUKernel InitWeightBias error.";
    FreeTmpBuffer();
    return RET_ERROR;
  }
  return RET_OK;
 }
  ret = InitBuffer();
  if (ret != RET_OK) {
    MS_LOG(ERROR) << "GruCPUKernel InitBuffer error.";
    FreeTmpBuffer();
 int GruCPUKernel::MallocRunBuffer() {
  if (!is_vec_) {
    matmul_buffer_[0] = reinterpret_cast<float *>(
      context_->allocator->Malloc(3 * gru_param_->row_align_ * gru_param_->input_size_ * sizeof(float)));
    if (matmul_buffer_[0] == nullptr) {
      MS_LOG(ERROR) << "GruCPUKernel malloc input * weight left matirx error.";
      return RET_ERROR;
    }
    matmul_buffer_[1] = reinterpret_cast<float *>(
      context_->allocator->Malloc(3 * gru_param_->row_align_ * gru_param_->hidden_size_ * sizeof(float)));
    if (matmul_buffer_[1] == nullptr) {
      MS_LOG(ERROR) << "GruCPUKernel malloc state * weight left matirx error.";
      return RET_ERROR;
    }
  }
  gate_buffer_ = reinterpret_cast<float *>(
    context_->allocator->Malloc(6 * gru_param_->batch_ * gru_param_->hidden_size_ * sizeof(float)));
  if (gate_buffer_ == nullptr) {
    MS_LOG(ERROR) << "GruCPUKernel malloc gate_buffer error.";
    return RET_ERROR;
  }
  return RET_OK;
@@ -153,22 +199,35 @@ int GruCPUKernel::Run() {
  MS_ASSERT(output_ptr);
  auto output_hidden_state = out_tensors_[1];
  memcpy(output_hidden_state->data_c(), hidden_state->data_c(), hidden_state->ElementsNum() * sizeof(float));
  int check_seq_len = gru_parm_->seq_len_;
  int check_seq_len = gru_param_->seq_len_;
  if (in_tensors_.size() == 6) {
    auto seq_len = reinterpret_cast<int *>(in_tensors_.at(5)->data_c());
    if (!std::equal(seq_len + 1, seq_len + gru_parm_->batch_, seq_len)) {
    if (!std::equal(seq_len + 1, seq_len + gru_param_->batch_, seq_len)) {
      MS_LOG(ERROR) << "different batch seq_len is currently not supported";
      return RET_ERROR;
    }
    check_seq_len = MSMIN(check_seq_len, MSMAX(0, seq_len[0]));
  }
  auto ret = MallocRunBuffer();
  if (ret != RET_OK) {
    MS_LOG(ERROR) << "GruCPUKernel MallocRunBuffer error.";
    return RET_ERROR;
  }
  if (is_vec_) {
    weight_g_ptr_ = reinterpret_cast<float *>(in_tensors_[1]->data_c());
    weight_r_ptr_ = reinterpret_cast<float *>(in_tensors_[2]->data_c());
    bias_ptr_ = reinterpret_cast<float *>(in_tensors_[3]->data_c());
  }
  MS_ASSERT(weight_g_ptr_ != nullptr);
  MS_ASSERT(weight_r_ptr_ != nullptr);
  MS_ASSERT(bias_ptr_ != nullptr);
  MS_ASSERT(gate_buffer_ != nullptr);
  Gru(output_ptr, input_ptr, weight_g_ptr_, weight_r_ptr_, bias_ptr_,
      reinterpret_cast<float *>(output_hidden_state->data_c()), gate_buffer_, check_seq_len, gru_parm_);
      reinterpret_cast<float *>(output_hidden_state->data_c()), gate_buffer_, matmul_buffer_, check_seq_len,
      gru_param_);
  FreeRunBuffer();
  return RET_OK;
 }
--- a/mindspore/lite/src/runtime/kernel/arm/fp32/gru_fp32.h
+++ b/mindspore/lite/src/runtime/kernel/arm/fp32/gru_fp32.h
@@ -26,7 +26,7 @@ class GruCPUKernel : public LiteKernel {
               const std::vector<lite::Tensor *> &outputs, const lite::InnerContext *ctx,
               const mindspore::lite::PrimitiveC *primitive)
      : LiteKernel(parameter, inputs, outputs, ctx, primitive) {
    gru_parm_ = reinterpret_cast<GruParameter *>(op_parameter_);
    gru_param_ = reinterpret_cast<GruParameter *>(op_parameter_);
  }
  ~GruCPUKernel() override { FreeTmpBuffer(); }
@@ -37,15 +37,20 @@ class GruCPUKernel : public LiteKernel {
 private:
  void FreeTmpBuffer();
  void FreeRunBuffer();
  int InitParam();
  int InitBuffer();
  int MallocRunBuffer();
  int InitWeightBias();
  float *gate_buffer_ = nullptr;
  float *weight_g_ptr_ = nullptr;
  float *weight_r_ptr_ = nullptr;
  float *bias_ptr_ = nullptr;
  GruParameter *gru_parm_ = nullptr;
  float *matmul_buffer_[2];
  int row_tile_ = 0;
  int col_tile_ = 0;
  bool is_vec_ = false;
  GruParameter *gru_param_ = nullptr;
 };
 }  // namespace mindspore::kernel
--- a/mindspore/lite/src/runtime/kernel/arm/fp32/lstm_fp32.cc
+++ b/mindspore/lite/src/runtime/kernel/arm/fp32/lstm_fp32.cc
@@ -57,24 +57,8 @@ void LstmCPUKernel::FreeRunBuffer() {
  }
 }
 int InitRightMatrix(float *dst, const float *src, int batch, int deep, int col, int col_align, bool is_vec) {
  for (int i = 0; i < batch; i++) {
    auto src_batch = src + i * col * deep;
    auto dst_batch = dst + i * col_align * deep;
 #ifdef ENABLE_AVX
    RowMajor2Col16Major(src_batch, dst_batch, col, deep);
 #elif defined(ENABLE_ARM32)
    RowMajor2Col4Major(src_batch, dst_batch, col, deep);
 #else
    RowMajor2Col8Major(src_batch, dst_batch, col, deep);
 #endif
  }
  return RET_OK;
 }
 int LstmCPUKernel::InitWeightBias() {
  auto weight_batch = lstm_param_->bidirectional_ ? 8 : 4;
  if (!is_vec_) {
    // malloc and init input * weight right matrix buffer
    auto weight_i = in_tensors_.at(1);
@@ -86,8 +70,8 @@ int LstmCPUKernel::InitWeightBias() {
      return RET_ERROR;
    }
    auto weight_i_data = reinterpret_cast<float *>(weight_i->data_c());
    InitRightMatrix(weight_i_ptr_, weight_i_data, weight_batch, lstm_param_->input_size_, lstm_param_->hidden_size_,
                    lstm_param_->col_align_, is_vec_);
    PackLstmWeight(weight_i_ptr_, weight_i_data, weight_batch, lstm_param_->input_size_, lstm_param_->hidden_size_,
                   lstm_param_->col_align_);
    // malloc and init state * weight right matrix buffer
    auto weight_h = in_tensors_.at(2);
@@ -99,8 +83,8 @@ int LstmCPUKernel::InitWeightBias() {
      return RET_ERROR;
    }
    auto weight_h_data = reinterpret_cast<float *>(weight_h->data_c());
    InitRightMatrix(weight_h_ptr_, weight_h_data, weight_batch, lstm_param_->hidden_size_, lstm_param_->hidden_size_,
                    lstm_param_->col_align_, is_vec_);
    PackLstmWeight(weight_h_ptr_, weight_h_data, weight_batch, lstm_param_->hidden_size_, lstm_param_->hidden_size_,
                   lstm_param_->col_align_);
    // init bias
    int bias_batch = lstm_param_->bidirectional_ ? 16 : 8;
@@ -235,7 +219,7 @@ int LstmCPUKernel::Run() {
  auto ret = MallocRunBuffer();
  if (ret != RET_OK) {
    MS_LOG(ERROR) << "LstmCPUKernel InitRunBuffer error.";
    MS_LOG(ERROR) << "LstmCPUKernel MallocRunBuffer error.";
    return RET_ERROR;
  }
@@ -244,7 +228,6 @@ int LstmCPUKernel::Run() {
    weight_h_ptr_ = reinterpret_cast<float *>(in_tensors_[2]->data_c());
    bias_ptr_ = reinterpret_cast<float *>(in_tensors_[3]->data_c());
  }
  MS_ASSERT(weight_h_ptr_);
  MS_ASSERT(weight_i_ptr_);
  MS_ASSERT(bias_ptr_);