Grad Check For RNN

bad3d4b6 · Yang Yu · ea5d6eae · bad3d4b6 · bad3d4b6 · bad3d4b6
3 changed file
--- a/paddle/operators/tensor_array_read_write_op.cc
+++ b/paddle/operators/tensor_array_read_write_op.cc
@@ -136,6 +136,17 @@ class ReadFromArrayOp : public ArrayOp {
      auto &dev_ctx = *pool.Borrow(place);
      framework::CopyFrom(x_array[offset], place, dev_ctx, out_tensor);
      out_tensor->set_lod(x_array[offset].lod());
+      if (Input("X") == "dynamic_rnn_0_output_array_fc_0.tmp_0_0@GRAD") {
+        VLOG(10) << "Offset = " << offset;
+        if (x_array[offset].numel() != 0) {
+          auto d = x_array[offset].dims();
+          std::ostringstream sout;
+          for (int64_t i = 0; i < d[0]; ++i) {
+            sout << x_array[offset].data<float>()[0 * d[1]] << ", ";
+          }
+          VLOG(10) << "Grad = " << sout.str();
+        }
+      }
    } else {
      VLOG(10) << "offset " << offset << " >= " << x_array.size();
    }

--- a/paddle/operators/while_op.cc
+++ b/paddle/operators/while_op.cc
@@ -129,6 +129,9 @@ class WhileGradOp : public framework::OperatorBase {
        auto &og_inside =
            detail::Ref(cur_scope.Var(inside_og_name),
                        "Cannot find inside gradient %s", inside_og_name);
+
+        VLOG(10) << "OG " << outside_og_name << " Type is "
+                 << og_outside.Type().name();
        if (og_outside.Type().hash_code() ==
            typeid(framework::LoDTensor).hash_code()) {
          auto &outside_tensor = og_outside.Get<framework::LoDTensor>();
@@ -145,7 +148,6 @@ class WhileGradOp : public framework::OperatorBase {
          inside_array.resize(outside_array.size());

          for (size_t j = 0; j < inside_array.size(); ++j) {
-            VLOG(10) << j << " " << outside_array[j].numel();
            if (outside_array[j].numel() != 0) {
              inside_array[j].set_lod(outside_array[j].lod());
              inside_array[j].ShareDataWith(outside_array[j]);
@@ -198,6 +200,17 @@ class WhileGradOp : public framework::OperatorBase {
        auto sum_op = framework::OpRegistry::CreateOp(
            "sum", {{"X", {pg_names[param_id], new_inside_name}}},
            {{"Out", {pg_names[param_id]}}}, framework::AttributeMap{});
+
+        VLOG(10) << "Accumulate the gradient of " << pg_names[param_id];
+
+        if (pg_names[param_id] == "W@GRAD") {
+          auto &w_g = detail::Ref(cur_scope.FindVar(new_inside_name))
+                          .Get<framework::LoDTensor>();
+          VLOG(10) << "W_G is" << w_g.data<float>()[0];
+        } else {
+          VLOG(10) << pg_names[param_id];
+        }
+
        sum_op->Run(cur_scope, dev_place);
        cur_scope.Rename(new_inside_name, inside_grad_name);
      }

--- a/python/paddle/v2/fluid/tests/test_dynrnn_gradient_check.py
+++ b/python/paddle/v2/fluid/tests/test_dynrnn_gradient_check.py
+import numpy
+import random
+import collections
+import paddle.v2.fluid as fluid
+import unittest
+import copy
+
+
+class Memory(object):
+    def __init__(self, shape, dtype='float32'):
+        self.ex = numpy.zeros(shape=shape, dtype=dtype)
+        self.cur = None
+
+    def update(self, val):
+        assert val.shape == self.ex.shape
+        assert val.dtype == self.ex.dtype
+        self.cur = val
+
+    def ex(self):
+        return self.ex
+
+    def next(self):
+        self.ex = self.cur
+        self.cur = None
+
+    def __next__(self):
+        self.next()
+
+    def reset(self):
+        self.ex = numpy.zeros(shape=self.ex.shape, dtype=self.ex.dtype)
+        self.cur = None
+
+
+class Output(object):
+    def __init__(self):
+        self.outs = []
+
+    def next_sequence(self):
+        self.outs.append([])
+
+    def out(self, val):
+        self.outs[-1].append(val)
+
+    def last(self):
+        return self.outs[-1][-1]
+
+
+class BaseRNN(object):
+    def __init__(self, ins, mems, params, outs, num_seq=5, max_seq_len=15):
+        self.num_seq = num_seq
+        self.inputs = collections.defaultdict(list)
+
+        for _ in xrange(num_seq):
+            seq_len = random.randint(1, max_seq_len - 1)
+            for iname in ins:
+                ishape = ins[iname].get('shape', None)
+                idtype = ins[iname].get('dtype', 'float32')
+                lst = []
+                for _ in xrange(seq_len):
+                    lst.append(numpy.random.random(size=ishape).astype(idtype))
+                self.inputs[iname].append(lst)
+
+        self.mems = dict()
+        for mname in mems:
+            mshape = mems[mname].get('shape', None)
+            mdtype = mems[mname].get('dtype', 'float32')
+            self.mems[mname] = Memory(shape=mshape, dtype=mdtype)
+
+        self.params = dict()
+        for pname in params:
+            pshape = params[pname].get('shape', None)
+            pdtype = params[pname].get('dtype', 'float32')
+            self.params[pname] = numpy.random.random(size=pshape).astype(pdtype)
+
+        self.outputs = dict()
+
+        for oname in outs:
+            self.outputs[oname] = Output()
+
+    def step(self, **kwargs):
+        pass
+
+    def exe(self):
+        retv = dict()
+        for out in self.outputs:
+            retv[out] = []
+
+        for seq_id in xrange(self.num_seq):
+            for mname in self.mems:
+                self.mems[mname].reset()
+            for out in self.outputs:
+                self.outputs[out].next_sequence()
+
+            iname0 = self.inputs.keys()[0]
+            seq_len = len(self.inputs[iname0][seq_id])
+
+            for step_id in xrange(seq_len):
+                xargs = dict()
+
+                for iname in self.inputs:
+                    xargs[iname] = self.inputs[iname][seq_id][step_id]
+
+                for mname in self.mems:
+                    xargs[mname] = self.mems[mname]
+
+                for pname in self.params:
+                    xargs[pname] = self.params[pname]
+
+                for out in self.outputs:
+                    xargs[out] = self.outputs[out]
+
+                self.step(**xargs)
+
+                for mname in self.mems:
+                    next(self.mems[mname])
+
+            for out in self.outputs:
+                retv[out].append(self.outputs[out].last())
+
+        for out in retv:
+            retv[out] = numpy.array(retv[out])
+        return retv
+
+    def to_feed(self, place):
+        feed_dict = dict()
+
+        for iname in self.inputs:
+            lod = [0]
+            np_flatten = []
+            for seq_id in xrange(len(self.inputs[iname])):
+                seq_len = len(self.inputs[iname][seq_id])
+                lod.append(lod[-1] + seq_len)
+                np_flatten.extend(self.inputs[iname][seq_id])
+
+            t = fluid.Tensor()
+            t.set(numpy.array(np_flatten), place)
+            t.set_lod([lod])
+            feed_dict[iname] = t
+
+        for pname in self.params:
+            feed_dict[pname] = self.params[pname]
+        return feed_dict
+
+    def get_numeric_gradient_of_param(self, param_name, delta=0.01):
+        p = self.params[param_name]
+        g = numpy.zeros(shape=p.shape, dtype=p.dtype)
+
+        for p_it, g_it in numpy.nditer([p, g], op_flags=['readwrite']):
+            o = float(p_it)
+            p_it[...] = o + delta
+            pos = self._exe_mean_out_()
+            p_it[...] = o - delta
+            neg = self._exe_mean_out_()
+            p_it[...] = o
+            g[:] = (pos - neg) / (delta * 2)
+        return g
+
+    def _exe_mean_out_(self):
+        outs = self.exe()
+        return numpy.array([o.mean() for o in outs.itervalues()]).mean()
+
+
+class SimpleMul(BaseRNN):
+    def __init__(self):
+        super(SimpleMul, self).__init__({
+            'X': {
+                'shape': [32]
+            }
+        }, {}, {'W': {
+            'shape': [32, 10]
+        }}, ['Out'])
+
+    def step(self, X, W, Out):
+        Out.out(numpy.matmul(X, W))
+
+
+class TestSimpleMul(unittest.TestCase):
+    def setUp(self):
+        self.python_impl = SimpleMul()
+
+    def test_forward(self):
+        program = fluid.Program()
+        startup_program = fluid.Program()
+        with fluid.program_guard(program, startup_program):
+            dat = fluid.layers.data(name='X', shape=[32], lod_level=1)
+
+            rnn = fluid.layers.DynamicRNN()
+            with rnn.block():
+                d = rnn.step_input(dat)
+                o = fluid.layers.fc(input=d,
+                                    param_attr='W',
+                                    bias_attr=False,
+                                    size=10,
+                                    act=None)
+                rnn.output(o)
+
+            out = rnn()
+            out = fluid.layers.sequence_pool(out, pool_type='last')
+            loss = fluid.layers.mean(x=out)
+            fluid.backward.append_backward_ops(loss)
+
+        cpu = fluid.CPUPlace()
+        exe = fluid.Executor(cpu)
+        out, w_g = exe.run(program,
+                           feed=self.python_impl.to_feed(cpu),
+                           fetch_list=[out, "W@GRAD"])
+        out_by_python = self.python_impl.exe()['Out']
+        self.assertTrue(numpy.allclose(out, out_by_python))
+        w_g_num = self.python_impl.get_numeric_gradient_of_param("W")
+        print w_g_num[0][0]
+        print w_g_num - w_g
+
+
+if __name__ == '__main__':
+    unittest.main()