add conv1d, conv1dcell, conv1d_transpose in to customized layers

2020-02-11 06:49:32 +00:00 · 2020-02-11 06:49:32 +00:00 · 907f777ab8
parent fd9e198ab6
commit 907f777ab8
1 changed files with 157 additions and 0 deletions
--- a/parakeet/modules/customized.py
+++ b/parakeet/modules/customized.py
@ -0,0 +1,157 @@
+from paddle import fluid
+import paddle.fluid.layers as F
+import paddle.fluid.dygraph as dg
+
+
+class Conv1D(dg.Conv2D):
+    """A standard Conv1D layer that use (B, C, T) data layout. It inherit Conv2D and 
+    use (B, C, 1, T) data layout to compute 1D convolution. Nothing more.
+    NOTE: we inherit Conv2D instead of encapsulate a Conv2D layer to make it a simple
+    layer, instead of a complex one. So we can easily apply weight norm to it.
+    """
+    def __init__(self,
+                 num_channels,
+                 num_filters,
+                 filter_size,
+                 stride=1,
+                 padding=0,
+                 dilation=1,
+                 groups=None,
+                 param_attr=None,
+                 bias_attr=None,
+                 use_cudnn=True,
+                 act=None,
+                 dtype='float32'):
+        super(Conv1D, self).__init__(num_channels,
+                                     num_filters, (1, filter_size),
+                                     stride=(1, stride),
+                                     padding=(0, padding),
+                                     dilation=(1, dilation),
+                                     groups=groups,
+                                     param_attr=param_attr,
+                                     bias_attr=bias_attr,
+                                     use_cudnn=use_cudnn,
+                                     act=act,
+                                     dtype=dtype)
+
+    def forward(self, x):
+        x = F.unsqueeze(x, [2])
+        x = super(Conv1D, self).forward(x)  # maybe risky here
+        x = F.squeeze(x, [2])
+        return x
+
+
+class Conv1DTranspose(dg.Conv2DTranspose):
+    def __init__(self,
+                 num_channels,
+                 num_filters,
+                 filter_size,
+                 padding=0,
+                 stride=1,
+                 dilation=1,
+                 groups=None,
+                 param_attr=None,
+                 bias_attr=None,
+                 use_cudnn=True,
+                 act=None,
+                 dtype='float32'):
+        super(Conv1DTranspose, self).__init__(num_channels,
+                                              num_filters, (1, filter_size),
+                                              output_size=None,
+                                              padding=(0, padding),
+                                              stride=(1, stride),
+                                              dilation=(1, dilation),
+                                              groups=groups,
+                                              param_attr=param_attr,
+                                              bias_attr=bias_attr,
+                                              use_cudnn=use_cudnn,
+                                              act=act,
+                                              dtype=dtype)
+
+    def forward(self, x):
+        x = F.unsqueeze(x, [2])
+        x = super(Conv1DTranspose, self).forward(x)  # maybe risky here
+        x = F.squeeze(x, [2])
+        return x
+
+
+class Conv1DCell(Conv1D):
+    """A causal convolve-1d cell. It uses causal padding, padding(receptive_field -1,  0).
+    But Conv2D in dygraph does not support asymmetric padding yet, we just pad
+    (receptive_field -1, receptive_field -1) and drop last receptive_field -1 steps in 
+    the output.
+    
+    It is a cell that it acts like an RNN cell. It does not support stride > 1, and it
+    ensures 1-to-1 mapping from input time steps to output timesteps.
+    """
+    def __init__(self,
+                 num_channels,
+                 num_filters,
+                 filter_size,
+                 dilation=1,
+                 causal=False,
+                 groups=None,
+                 param_attr=None,
+                 bias_attr=None,
+                 use_cudnn=True,
+                 act=None,
+                 dtype='float32'):
+        receptive_field = 1 + dilation * (filter_size - 1)
+        padding = receptive_field - 1 if causal else receptive_field // 2
+        self._receptive_field = receptive_field
+        self.causal = causal
+        super(Conv1DCell, self).__init__(num_channels,
+                                         num_filters,
+                                         filter_size,
+                                         stride=1,
+                                         padding=padding,
+                                         dilation=dilation,
+                                         groups=groups,
+                                         param_attr=param_attr,
+                                         bias_attr=bias_attr,
+                                         use_cudnn=use_cudnn,
+                                         act=act,
+                                         dtype=dtype)
+
+    def forward(self, x):
+        # it ensures that ouput time steps == input time steps
+        time_steps = x.shape[-1]
+        x = super(Conv1DCell, self).forward(x)
+        if x.shape[-1] != time_steps:
+            x = x[:, :, :time_steps]
+        return x
+
+    @property
+    def receptive_field(self):
+        return self._receptive_field
+
+    def start_sequence(self):
+        if not self.causal:
+            raise ValueError(
+                "Only causal conv1d shell should use start sequence")
+        if self.receptive_field == 1:
+            raise ValueError(
+                "Convolution block with receptive field = 1 does not need"
+                " to be implemented as a Conv1DCell. Conv1D suffices")
+        self._buffer = None
+        self._reshaped_weight = F.reshape(self.weight, (self._num_filters, -1))
+
+    def add_input(self, x_t):
+        batch_size, c_in, _ = x_t.shape
+        if self._buffer is None:
+            self._buffer = F.zeros((batch_size, c_in, self.receptive_field),
+                                   dtype=x_t.dtype)
+        self._buffer = F.concat([self._buffer[:, :, 1:], x_t], -1)
+        if self._dilation[1] > 1:
+            input = F.strided_slice(self._buffer,
+                                    axes=[2],
+                                    starts=[0],
+                                    ends=[self.receptive_field],
+                                    strides=[self._dilation[1]])
+        else:
+            input = self._buffer
+        input = F.reshape(input, (batch_size, -1))
+        y_t = F.matmul(input, self._reshaped_weight, transpose_y=True)
+        y_t = y_t + self.bias
+        y_t = F.unsqueeze(y_t, [-1])
+        return y_t