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paddlepaddle--paddle/test/legacy_test/test_fused_transformer_encoder_layer.py
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2026-07-13 12:40:42 +08:00

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Python

# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import unittest
import numpy as np
from utils import static_guard
import paddle
from paddle.base.framework import in_dygraph_mode
from paddle.incubate.nn import FusedTransformerEncoderLayer
from paddle.nn import TransformerEncoderLayer
class TestFusedTransformerEncoderLayer(unittest.TestCase):
def setActivation(self):
self.activation = 'gelu'
def setPreLayerNorm(self):
self.pre_layer_norm = False
def setAttnMask(self):
self.has_attn_mask = True
def setUp(self):
self.batch_size = np.random.randint(1, 8)
self.query_length = np.random.randint(1, 128)
self.nhead = 16
self.head_dim = 4
self.num_heads = self.nhead
self.d_model = self.head_dim * self.num_heads
self.embed_dim = self.d_model
self.dim_feedforward = np.random.randint(1, 32)
self.dropout_rate = 0
self.attn_dropout_rate = None
self.act_dropout_rate = None
self.attn_mask_type = np.float64
self.key_length = self.query_length
self.dtype = 'float32'
self.setActivation()
self.setPreLayerNorm()
self.setAttnMask()
self.rtol = 1e-3
# FIXME(limin29): Because there is a problem with the test precision
# on A100, atol is temporarily set to 1e-2, and it will be
# changed back after the precision problem is solved.
self.atol = 1e-2
if "V100" in paddle.device.cuda.get_device_name():
self.atol = 1e-4
def fused_weight(self, weight, num_head):
a = paddle.transpose(weight, perm=[1, 0])
return paddle.reshape(
a, shape=[1, num_head, int(a.shape[0] / num_head), a.shape[1]]
)
def fused_qkv(self, q, k, v, num_head):
fq = self.fused_weight(q, num_head)
fk = self.fused_weight(k, num_head)
fv = self.fused_weight(v, num_head)
return paddle.concat(x=[fq, fk, fv], axis=0)
def test_out(self):
if in_dygraph_mode():
return
paddle.seed(42)
base_encoder = TransformerEncoderLayer(
self.d_model,
self.nhead,
self.dim_feedforward,
self.dropout_rate,
self.activation,
self.attn_dropout_rate,
self.act_dropout_rate,
self.pre_layer_norm,
)
src = np.random.rand(
self.batch_size, self.query_length, self.embed_dim
).astype(self.dtype)
if self.has_attn_mask:
attn_mask = np.ones(
(
self.batch_size,
self.num_heads,
self.query_length,
self.key_length,
),
dtype=self.attn_mask_type,
)
attn_mask_tensor = paddle.to_tensor(attn_mask)
else:
attn_mask = None
attn_mask_tensor = None
dout = np.random.random(src.shape).astype(self.dtype)
base_out = base_encoder(
paddle.to_tensor(src, stop_gradient=False), attn_mask_tensor
)
paddle.autograd.backward([base_out], [paddle.to_tensor(dout)], True)
fused_encoder = FusedTransformerEncoderLayer(
self.d_model,
self.nhead,
self.dim_feedforward,
self.dropout_rate,
self.activation,
self.attn_dropout_rate,
self.act_dropout_rate,
self.pre_layer_norm,
)
fused_encoder.ffn._linear1_weight.set_value(base_encoder.linear1.weight)
fused_encoder.ffn._linear1_bias.set_value(base_encoder.linear1.bias)
fused_encoder.ffn._linear2_weight.set_value(base_encoder.linear2.weight)
fused_encoder.ffn._linear2_bias.set_value(base_encoder.linear2.bias)
if self.pre_layer_norm:
fused_encoder.ffn._ln1_scale.set_value(base_encoder.norm2.weight)
fused_encoder.ffn._ln1_bias.set_value(base_encoder.norm2.bias)
else:
fused_encoder.ffn._ln2_scale.set_value(base_encoder.norm2.weight)
fused_encoder.ffn._ln2_bias.set_value(base_encoder.norm2.bias)
fused_encoder.fused_attn.linear_weight.set_value(
base_encoder.self_attn.out_proj.weight
)
fused_encoder.fused_attn.linear_bias.set_value(
base_encoder.self_attn.out_proj.bias
)
if self.pre_layer_norm:
fused_encoder.fused_attn.pre_ln_scale.set_value(
base_encoder.norm1.weight
)
fused_encoder.fused_attn.pre_ln_bias.set_value(
base_encoder.norm1.bias
)
else:
fused_encoder.fused_attn.ln_scale.set_value(
base_encoder.norm1.weight
)
fused_encoder.fused_attn.ln_bias.set_value(base_encoder.norm1.bias)
q = base_encoder.self_attn.q_proj.weight
q_bias = base_encoder.self_attn.q_proj.bias
k = base_encoder.self_attn.k_proj.weight
k_bias = base_encoder.self_attn.k_proj.bias
v = base_encoder.self_attn.v_proj.weight
v_bias = base_encoder.self_attn.v_proj.bias
qkv_weight = self.fused_qkv(q, k, v, self.num_heads)
fused_encoder.fused_attn.qkv_weight.set_value(qkv_weight)
tmp = paddle.concat(x=[q_bias, k_bias, v_bias], axis=0)
qkv_bias = paddle.reshape(
tmp,
shape=[3, self.num_heads, int(tmp.shape[0] / 3 / self.num_heads)],
)
fused_encoder.fused_attn.qkv_bias.set_value(qkv_bias)
fused_out = fused_encoder(
paddle.to_tensor(src, stop_gradient=False), attn_mask_tensor
)
paddle.autograd.backward([fused_out], [paddle.to_tensor(dout)], True)
correct_ffn_str = f'd_model={self.d_model}, dim_feedforward={self.dim_feedforward}, dropout_rate={self.dropout_rate}, epsilon={fused_encoder.ffn._epsilon}, activation={self.activation}, act_dropout_rate={self.dropout_rate}, normalize_before={self.pre_layer_norm}, dtype={self.dtype}'
self.assertTrue(fused_encoder.ffn.extra_repr(), correct_ffn_str)
correct_attn_str = f'embed_dim={self.embed_dim}, num_heads={self.num_heads}, dropout_rate={self.dropout_rate}, attn_dropout_rate={self.dropout_rate}, epsilon={fused_encoder.fused_attn._epsilon}, kdim={None}, vdim={None}, normalize_before={self.pre_layer_norm}, need_weights={False}, dtype={self.dtype}'
self.assertTrue(fused_encoder.fused_attn.extra_repr(), correct_attn_str)
np.testing.assert_allclose(
fused_out.numpy(), base_out.numpy(), rtol=self.rtol, atol=self.atol
)
np.testing.assert_allclose(
fused_out.grad.numpy(),
base_out.grad.numpy(),
rtol=self.rtol,
atol=self.atol,
)
class TestFusedTransformerEncoderLayerAct(TestFusedTransformerEncoderLayer):
def setActivation(self):
self.activation = 'relu'
class TestFusedTransformerEncoderLayerPreLayerNorm(
TestFusedTransformerEncoderLayer
):
def setPreLayerNorm(self):
self.pre_layer_norm = True
class TestFusedTransformerEncoderLayerAttnMaskIsNone(
TestFusedTransformerEncoderLayer
):
def setAttnMask(self):
self.has_attn_mask = False
class TestFusedTransformerEncoderLayerPreLnTrueAttnMaskIsNone(
TestFusedTransformerEncoderLayer
):
def setPreLayerNorm(self):
self.pre_layer_norm = True
def setAttnMask(self):
self.has_attn_mask = False
class TestPirFusedTransformerEncoderLayer(unittest.TestCase):
def run_program(self):
with static_guard():
paddle.seed(1)
startup = paddle.static.Program()
main = paddle.static.Program()
with paddle.static.program_guard(main, startup):
enc_input = paddle.rand((2, 4, 128))
attn_mask = paddle.rand((2, 2, 4, 4))
encoder_layer = FusedTransformerEncoderLayer(128, 2, 512)
enc_output = encoder_layer(enc_input, attn_mask)
exe = paddle.static.Executor()
exe.run(startup)
out = exe.run(feed={}, fetch_list=[enc_output])
return out
def test_pir(self):
out1 = self.run_program()
with paddle.pir_utils.IrGuard():
out2 = self.run_program()
np.testing.assert_allclose(out1, out2)
if __name__ == "__main__":
unittest.main()