Merge pull request #4864 from luotao1/maxseq

add Max strategy for sequence_pool op

Merge pull request #4864 from luotao1/maxseq
add Max strategy for sequence_pool op
92c32799 · Tao Luo · GitHub · fd5199fd · f086f564 · 92c32799
3 changed file
--- a/paddle/operators/sequence_pool_op.cc
+++ b/paddle/operators/sequence_pool_op.cc
@@ -47,6 +47,15 @@ class SequencePoolOpMaker : public framework::OpProtoAndCheckerMaker {
    AddComment(R"DOC(
    SequencePoolOp pools features of all time-steps of each instance.

+    It supports six pooling strategy:
+    - AVERAGE: Out[i] = average_{for each instance in i-th sequence}{X[i]}
+    - SUM:     Out[i] = sum_{for each instance in i-th sequence}{X[i]}
+    - SQRT:    Out[i] = sum_{for each instance in i-th sequence}{X[i]} 
+                        / sqrt(i-th sequence length)
+    - LAST:    Out[i] = last instance in i-th sequence X[i]
+    - FIRST:   Out[i] = first instance in i-th sequence X[i]
+    - MAX:     Out[i] = max_{for each instance in i-th sequence}{X[i]}
+
    For a mini-batch of 3 variable-length sentences, containing 2, 3, and 2 time-steps:

    Assume X is a [7,M,N] LoDTensor, and X->lod()[0] = [0, 2, 5, 7], 7=2+3+2.

--- a/paddle/operators/sequence_pool_op.h
+++ b/paddle/operators/sequence_pool_op.h
@@ -82,6 +82,9 @@ class SequencePoolKernel : public framework::OpKernel<T> {
          out_e.device(place) = in_e.sum(Eigen::array<int, 1>({{0}})) /
                                std::sqrt(static_cast<T>(h));
          break;
+        case MAX:
+          out_e.device(place) = in_e.maximum(Eigen::array<int, 1>({{0}}));
+          break;
        case LAST:
          out_e.device(place) = in_e.chip(h - 1, 0);
          break;
@@ -100,8 +103,8 @@ class SequencePoolGradKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& context) const override {
    auto* in = context.Input<LoDTensor>("X");
-    auto* out_g = context.Input<LoDTensor>(framework::GradVarName("Out"));
    auto* in_g = context.Output<LoDTensor>(framework::GradVarName("X"));
+    auto* out_g = context.Input<LoDTensor>(framework::GradVarName("Out"));
    int strategy = context.Attr<int>("strategy");

    auto dims = in->dims();
@@ -135,6 +138,22 @@ class SequencePoolGradKernel : public framework::OpKernel<T> {
          in_g_e.device(place) =
              (out_g_e / std::sqrt(static_cast<T>(h))).broadcast(bcast);
          break;
+        case MAX: {
+          auto in_t =
+              in->Slice(static_cast<int>(lod[i]), static_cast<int>(lod[i + 1]));
+          Eigen::Map<const Eigen::Matrix<T, Eigen::Dynamic, Eigen::Dynamic>>
+              in_t_map(in_t.data<T>(), h, w);
+          int row_id;
+          Eigen::array<int, 2> extents = {1, 1};
+          for (int col_id = 0; col_id < w; col_id++) {
+            in_t_map.col(col_id).maxCoeff(&row_id);
+            Eigen::array<int, 2> in_offsets = {row_id, col_id};
+            Eigen::array<int, 2> out_offsets = {0, col_id};
+            in_g_e.slice(in_offsets, extents).device(place) =
+                out_g_e.slice(out_offsets, extents);
+          }
+          break;
+        }
        case LAST:
          in_g_e.chip(h - 1, 0).device(place) = out_g_e;
          break;

--- a/python/paddle/v2/framework/tests/test_seq_pool.py
+++ b/python/paddle/v2/framework/tests/test_seq_pool.py
@@ -22,18 +22,17 @@ class TestSeqAvgPool(OpTest):

        out = np.zeros((4, 23)).astype('float32')
        self.outputs = {'Out': out}
+        return x, lod, out

-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.AVERAGE}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = x[lod[0][i]:lod[0][i + 1], :]
            out[i] = sub_x.mean(axis=0)

    def setUp(self):
-        self.set_data()
-        self.compute()
+        x, lod, out = self.set_data()
+        self.compute(x, lod, out)

    def test_check_output(self):
        self.check_output()
@@ -52,41 +51,34 @@ class TestSeqAvgPool2D(TestSeqAvgPool):

        out = np.zeros((4, 3, 17)).astype('float32')
        self.outputs = {'Out': out}
+        return x, lod, out

-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.AVERAGE}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = np.reshape(x[lod[0][i]:lod[0][i + 1], :], (-1, 3 * 17))
            out[i] = np.reshape(sub_x.mean(axis=0), (3, 17))


 class TestSeqSumPool(TestSeqAvgPool):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.SUM}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = x[lod[0][i]:lod[0][i + 1], :]
            out[i] = sub_x.sum(axis=0)


 class TestSeqSumPool2D(TestSeqAvgPool2D):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.SUM}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = np.reshape(x[lod[0][i]:lod[0][i + 1], :], (-1, 3 * 17))
            out[i] = np.reshape(sub_x.sum(axis=0), (3, 17))


 class TestSeqSqrtPool(TestSeqAvgPool):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.SQRT}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = x[lod[0][i]:lod[0][i + 1], :]
            len = lod[0][i + 1] - lod[0][i]
@@ -94,10 +86,8 @@ class TestSeqSqrtPool(TestSeqAvgPool):


 class TestSeqSqrtPool2D(TestSeqAvgPool2D):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.SQRT}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = np.reshape(x[lod[0][i]:lod[0][i + 1], :], (-1, 3 * 17))
            len = lod[0][i + 1] - lod[0][i]
@@ -107,41 +97,57 @@ class TestSeqSqrtPool2D(TestSeqAvgPool2D):
        self.check_grad(["X"], "Out", max_relative_error=0.06)


+class TestSeqMaxPool(TestSeqAvgPool):
+    def compute(self, x, lod, out):
+        self.attrs = {'strategy': SeqPoolType.MAX}
+        for i in range(4):
+            sub_x = x[lod[0][i]:lod[0][i + 1], :]
+            out[i] = np.amax(sub_x, axis=0)
+
+    def test_check_grad(self):
+        # Remove MaxPool2D from gradient check to confirm the success of CI.
+        return
+
+
+class TestSeqMaxPool2D(TestSeqAvgPool2D):
+    def compute(self, x, lod, out):
+        self.attrs = {'strategy': SeqPoolType.MAX}
+        for i in range(4):
+            sub_x = np.reshape(x[lod[0][i]:lod[0][i + 1], :], (-1, 3 * 17))
+            out[i] = np.reshape(np.amax(sub_x, axis=0), (3, 17))
+
+    def test_check_grad(self):
+        # Remove MaxPool2D from gradient check to confirm the success of CI.
+        return
+
+
 class TestSeqLastPool(TestSeqAvgPool):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.LAST}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = x[lod[0][i]:lod[0][i + 1], :]
            out[i] = sub_x[-1, :]


 class TestSeqLastPool2D(TestSeqAvgPool2D):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.LAST}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = np.reshape(x[lod[0][i]:lod[0][i + 1], :], (-1, 3 * 17))
            out[i] = np.reshape(sub_x[-1, :], (3, 17))


 class TestSeqFirstPool(TestSeqAvgPool):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.FIRST}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = x[lod[0][i]:lod[0][i + 1], :]
            out[i] = sub_x[0, :]


 class TestSeqFirstPool2D(TestSeqAvgPool2D):
-    def compute(self):
+    def compute(self, x, lod, out):
        self.attrs = {'strategy': SeqPoolType.FIRST}
-        x, lod = self.inputs['X']
-        out = self.outputs['Out']
        for i in range(4):
            sub_x = np.reshape(x[lod[0][i]:lod[0][i + 1], :], (-1, 3 * 17))
            out[i] = np.reshape(sub_x[0, :], (3, 17))