| class HyperConv1D(layers.Layer): |
| def __init__(self, d_model, k=7, mem_size=64, hyper_dim=128, dropout=0.0): |
| super().__init__() |
| assert k % 2 == 1 |
| self.k = k |
| self.d_model = d_model |
| self.mem_size = mem_size |
|
|
| |
| self.input_proj = layers.Dense(d_model, name="input_proj") |
|
|
| |
| self.local_conv = layers.DepthwiseConv1D(kernel_size=k, padding='same', activation='silu') |
| self.local_proj = layers.Dense(d_model, name="local_proj") |
|
|
| |
| self.hyper = tf.keras.Sequential([ |
| layers.Dense(hyper_dim, activation='gelu'), |
| layers.Dense(d_model) |
| ], name="hyper") |
|
|
| |
| self.mem_keys = self.add_weight((mem_size, d_model), initializer='glorot_uniform', trainable=True) |
| self.mem_vals = self.add_weight((mem_size, d_model), initializer='glorot_uniform', trainable=True) |
| self.mem_proj = layers.Dense(d_model) |
|
|
| self.norm = layers.LayerNormalization() |
| self.attn_pool = layers.Dense(1) |
|
|
| def call(self, x): |
| x_in = x |
| x_dtype = x.dtype |
|
|
| |
| x_proj = self.input_proj(x) |
| |
| mem_dtype = self.mem_keys.dtype |
| x_proj = tf.cast(x_proj, mem_dtype) |
|
|
| |
| out_local = self.local_conv(x_proj) |
| |
| global_z = self.attn_pool(x_proj) |
| global_z = tf.nn.softmax(global_z, axis=1) |
| global_z = tf.reduce_sum(x_proj * global_z, axis=1) |
|
|
| scale = tf.expand_dims(tf.nn.sigmoid(self.hyper(global_z)), 1) |
| out_local = out_local * scale |
| out_local = self.local_proj(out_local) |
|
|
|
|
| |
| sims = tf.matmul(x_proj, self.mem_keys, transpose_b=True) / tf.math.sqrt(tf.cast(self.d_model, mem_dtype)) |
| attn = tf.nn.softmax(sims, axis=-1) |
| mem_read = tf.matmul(attn, self.mem_vals) |
| mem_read = self.mem_proj(mem_read) |
|
|
| |
| out = out_local + mem_read |
| out = self.norm(x_proj + out) |
| out = tf.nn.silu(out) |
|
|
| |
| return tf.cast(out, x_dtype) |
|
|
